US20240060832A1 - Dual heat path temperature sensor - Google Patents
Dual heat path temperature sensor Download PDFInfo
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- US20240060832A1 US20240060832A1 US18/353,040 US202318353040A US2024060832A1 US 20240060832 A1 US20240060832 A1 US 20240060832A1 US 202318353040 A US202318353040 A US 202318353040A US 2024060832 A1 US2024060832 A1 US 2024060832A1
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- G01K17/06—Measuring quantity of heat conveyed by flowing media, e.g. in heating systems e.g. the quantity of heat in a transporting medium, delivered to or consumed in an expenditure device
- G01K17/08—Measuring quantity of heat conveyed by flowing media, e.g. in heating systems e.g. the quantity of heat in a transporting medium, delivered to or consumed in an expenditure device based upon measurement of temperature difference or of a temperature
- G01K17/10—Measuring quantity of heat conveyed by flowing media, e.g. in heating systems e.g. the quantity of heat in a transporting medium, delivered to or consumed in an expenditure device based upon measurement of temperature difference or of a temperature between an inlet and an outlet point, combined with measurement of rate of flow of the medium if such, by integration during a certain time-interval
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- A61B5/6801—Arrangements of detecting, measuring or recording means, e.g. sensors, in relation to patient specially adapted to be attached to or worn on the body surface
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- G01K7/02—Measuring temperature based on the use of electric or magnetic elements directly sensitive to heat ; Power supply therefor, e.g. using thermoelectric elements using thermoelectric elements, e.g. thermocouples
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Definitions
- This relates generally to temperature sensing systems and methods, and more particularly to temperature sensing systems and methods configured to measure internal body temperature and/or ambient temperature.
- Electronic devices can include a wearable device to measure internal body temperature. Electronic devices can also measure ambient temperature.
- thermopile can include a series-connected thermocouples and output a voltage measurement that is directly proportional to a temperature gradient and/or heat flux.
- the electronic device can include a temperature sensing system that includes at least two thermopiles, which form concentric geometries.
- the temperature sensing system can include a step up in height (e.g., a height differential) between the at least two thermopiles.
- the step up in height can complicate integration within compact housing (e.g., within a smart watch) due to space considerations for the temperature sensing system.
- an improved temperature sensing system e.g., dual heat flux sensor
- the improved temperature sensing system can include thermopiles with a height difference that is less than a threshold height difference (e.g., less than a difference of 10, 100, or 1000 microns in height between thermopiles).
- the temperature sensing system can include a sensing surface (e.g., a glass layer) embedded with thermopiles, such as an inner thermopile (e.g., first thermopile) and an outer thermopile (e.g., second thermopile).
- thermopile is associated with a respective heat path based on a temperature gradient between a top surface of the respective thermopile and a bottom surface of the respective thermopile.
- the inner thermopile and the outer thermopile can have different heat paths (e.g., temperature gradients).
- Temperature gradient measurements of the thermopiles e.g., inner thermopile, outer thermopile
- heat flux e.g., through an electronic device
- surface temperature of objects contacting housing of the electronic device e.g., ambient temperature
- body temperature of a user wearing the electronic device e.g., and so forth.
- Processing circuitry of the temperature sensing system or processing circuitry of the electronic device can leverage temperature gradient measurements of the thermopiles to account for variances in thermal resistance of skin and/or air (e.g., amount of fat tissue, wind speed, humidity) to accurately determine ambient temperature and/or internal body temperature.
- the processing circuitry of the temperature sensing system or the processing circuitry of the electronic device can use a temperature gradient of the inner thermopile, a temperature gradient of the outer thermopile, a lateral temperature difference between the inner thermopile and the outer thermopile, an absolute temperature of at least one surface of the inner thermopile or the outer thermopile, surface area of a heat path associated with the inner thermopile exposed to skin and/or air, surface area of a heat path associated with the outer thermopile exposed to skin and/or air, and so forth as inputs.
- FIGS. 1 A- 1 E illustrate example systems that can include a touch screen according to examples of the disclosure.
- FIG. 2 illustrates a block diagram of an example electronic device according to examples of the disclosure.
- FIG. 3 illustrates an example wearable device that includes an example temperature sensing system to measure thermal resistance of skin and internal body temperature according to examples of the disclosure.
- FIG. 4 illustrates an example wearable device that includes an example temperature sensing system to measure thermal resistance of air and ambient temperature according to examples of the disclosure.
- FIG. 5 illustrates a cross-section of an example temperature sensing system according to examples of the disclosure.
- FIG. 6 illustrates a cross-sectional side view of an example temperature sensing system according to examples of the disclosure.
- FIG. 7 A illustrates an example temperature sensing system including example inner and outer thermopiles forming concentric geometries according to examples of the disclosure.
- FIG. 7 B illustrates a top view of an example temperature sensing system including an additional thermopile between the inner and outer thermopiles according to examples of the disclosure.
- FIG. 8 A illustrates a schematic illustration of an example thermopile according to examples of the disclosure.
- FIG. 8 B illustrates a top view of example inner and outer thermopiles according to examples of the disclosure.
- FIGS. 9 A- 9 B illustrate a top view and a cross-sectional side view of an example wearable device that includes one or more temperature sensing systems according to examples of the disclosure.
- FIG. 10 illustrates a process for measuring internal temperature and/or ambient temperature according to some examples of the disclosure.
- thermopiles that form concentric geometries and are uniform in height (e.g., no step up between thermopiles).
- the temperature sensing system can include thermopiles with a height difference that is less than a threshold height difference (e.g., less than a difference of 10, 100, or 1000 microns in height between thermopiles).
- Processing circuitry of the temperature sensing system or processing circuitry of an electronic device can leverage temperature gradient measurements of the thermopiles to account for variances in thermal resistance of skin and/or air (e.g., amount of fat tissue, wind speed, humidity) to accurately determine ambient temperature and/or internal body temperature.
- the processing circuitry of the temperature sensing system or the processing circuitry of the electronic device can use a temperature gradient of the inner thermopile, a temperature gradient of the outer thermopile, a lateral temperature difference between the inner thermopile and the outer thermopile, an absolute temperature of at least one surface of the inner thermopile or the outer thermopile, surface area of a heat path associated with the inner thermopile exposed to skin and/or air, surface area of a heat path associated with the outer thermopile exposed to skin and/or air, and so forth as inputs.
- the temperature sensing system can include four absolute temperature sensors forming a concentric ring structure.
- a first absolute temperature sensor can measure a first absolute temperature at a first surface (e.g., bottom surface) of the inner thermopile
- a second absolute temperature sensor can measure a second absolute temperature at a first surface (e.g., bottom surface) of the outer thermopile
- a third absolute temperature sensor can measure a third absolute temperature at a second surface (e.g., top surface) of the inner thermopile
- a fourth absolute temperature sensor can measure a fourth absolute temperature at a second surface (e.g., top surface) of the outer thermopile.
- the processing circuitry of the temperature sensing system or the processing circuitry of the electronic device can determine thermal resistance of skin and internal body temperature and/or thermal resistance of air and ambient temperature.
- the processing circuitry of the temperature sensing system or the processing circuitry of the electronic device can determine thermal resistance of skin and internal body temperature and/or thermal resistance of air and ambient temperature using the temperature gradient of the inner thermopile, the temperature gradient of the outer thermopile, and least two absolute temperatures (e.g., first and second absolute temperatures, first and third absolute temperatures, third and fourth absolute temperatures, and so forth).
- the processing circuitry of the temperature sensing system or the processing circuitry of the electronic device can determine thermal resistance of skin and internal body temperature and/or thermal resistance of air and ambient temperature using any suitable combination of the temperature gradient of the inner thermopile, the temperature gradient of the outer thermopile, the lateral temperature difference between the inner thermopile and the outer thermopile, and one or more absolute temperatures.
- FIGS. 1 A- 1 E illustrate examples of systems, optionally with touch screens (e.g., capacitive touch screens), that can include an example temperature sensing system according to examples of the disclosure.
- FIG. 1 A illustrates an example mobile telephone 136 that optionally includes a touch screen 124 and can include an example temperature sensing system according to examples of the disclosure.
- FIG. 1 B illustrates an example digital media player 140 that optionally includes a touch screen 126 and can include an example temperature sensing system according to examples of the disclosure.
- FIG. 1 C illustrates an example personal computer 144 that optionally includes a touch screen 128 and can include an example temperature sensing system according to examples of the disclosure.
- FIG. 1 A illustrates an example mobile telephone 136 that optionally includes a touch screen 124 and can include an example temperature sensing system according to examples of the disclosure.
- FIG. 1 B illustrates an example digital media player 140 that optionally includes a touch screen 126 and can include an example temperature sensing system according to examples of the disclosure.
- FIG. 1 C illustrates
- FIG. 1 D illustrates an example tablet computing device 148 that optionally includes a touch screen 130 and can include an example temperature sensing system according to examples of the disclosure.
- FIG. 1 E illustrates an example wearable device 150 (e.g., a watch) that optionally includes a touch screen 152 and can include an example temperature sensing system according to examples of the disclosure. Wearable device 150 can be coupled to a user via strap 154 or any other suitable fastener. It should be understood that the example devices illustrated in FIGS. 1 A- 1 E are provided by way of example, and other devices can include an example temperature sensing system according to examples of the disclosure. Additionally, although the devices illustrated in FIGS. 1 A- 1 E include touch screens, in some examples, the devices may have a non-touch sensitive display or no display.
- FIG. 2 illustrates a block diagram of an example electronic device 200 , according to examples of the disclosure.
- the electronic device 200 can measure and/or display ambient temperature and/or internal body temperature based on temperature measurements from the temperature sensing system (e.g., dual heat flux sensor 214 and absolute temperature sensor 216 ).
- the electronic device 200 can be included in, for example, mobile telephone 136 , digital media player 140 , personal computer 144 , tablet computing device 148 , wearable device 150 , or any mobile or non-mobile computing device.
- the electronic device 200 can include an integrated display (e.g., touch screen) 212 to display images and to detect touch and/or proximity (e.g., hover) events from an object (e.g., active or passive stylus or finger) at or proximate to the surface of the display 212 .
- an integrated display e.g., touch screen
- proximity e.g., hover
- an object e.g., active or passive stylus or finger
- the electronic device 200 can include a power source 208 (e.g., energy storage device such as a battery), processor 204 , program storage device 210 and/or memory 206 , wireless communication circuitry 202 , and a temperature sensing system (e.g., a dual heat flux sensor 214 and absolute temperature sensor 216 ).
- the processor 204 can control some or all of the operations of the electronic device 200 .
- the processor 204 can communicate, either directly or indirectly, with some or all of the other components of the electronic device 200 .
- a system bus or other communication mechanism can provide communication between the power source 208 , the processor 204 , the display 212 , the program storage device 210 , the memory 206 , the wireless communication circuitry 202 , and the temperature sensing system (e.g., a dual heat flux sensor 214 and absolute temperature sensor 216 ).
- the temperature sensing system e.g., a dual heat flux sensor 214 and absolute temperature sensor 216 .
- the processor 204 can be implemented as any electronic device capable of processing, receiving, or transmitting data or instructions, whether such data or instructions is in the form of software or firmware or otherwise encoded.
- the processor 204 can include a microprocessor, a central processing unit (CPU), an application-specific integrated circuit (ASIC), a digital signal processor (DSP), a controller, or a combination of such devices.
- the term “processor” or “processing circuitry” is meant to encompass a single processor or processing unit, multiple processors, multiple processing units, or other suitably configured computing element or elements.
- processor 204 can provide part or all of the processing systems or processors described with reference to any of FIGS. 3 - 8 .
- the processor 204 can receive touch input to the display 212 or other input devices and perform actions based on the outputs.
- the processor 204 can be connected to the program storage 210 (and/or memory 206 ) and a display controller/driver to generate images on the display screen.
- the display screen includes, but is not limited to, Liquid Crystal Display (LCD) displays, Light-Emitting Diode (LED) displays, including Organic LED (OLED), Active-Matrix Organic LED (AMOLED), Passive-Matrix Organic LED (PMOLED) displays, a projector, a holographic projector, a retinal projector, or other suitable display.
- the display driver can provide voltages on select (e.g., gate) lines to each pixel transistor and can provide data signals along data lines to these same transistors to control the pixel display image for the display 212 .
- the processor 204 can cause a display image on the display 212 , such as a display image of a user interface (UI) or display a notification indicating ambient temperature and/or internal body temperature, and can use touch processor and/or touch controller to detect a touch on or near the display 212 , such as a touch input to the displayed UI when the electronic device 200 includes a touch screen.
- UI user interface
- touch processor and/or touch controller can detect a touch on or near the display 212 , such as a touch input to the displayed UI when the electronic device 200 includes a touch screen.
- the touch input can be used by computer programs stored in program storage 210 to perform actions that can include, but are not limited to, moving an object such as a cursor or pointer, scrolling or panning, adjusting control settings, opening a file or document, viewing a menu, making a selection, executing instructions, operating a peripheral device connected to the host device, answering a telephone call, placing a telephone call, terminating a telephone call, changing the volume or audio settings, storing information related to telephone communications such as addresses, frequently dialed numbers, received calls, missed calls, logging onto a computer or a computer network, permitting authorized individuals access to restricted areas of the computer or computer network, loading a user profile associated with a user's preferred arrangement of the computer desktop, permitting access to web content, launching a particular program, encrypting or decoding a message, and/or the like.
- the processor 204 can also perform additional functions that may not be related to touch processing or temperature sensing.
- firmware stored in memory 206 and/or stored in program storage 210 and executed by the processor 204 or other processing circuitry of the electronic device 200 .
- the firmware can also be stored and/or transported within any non-transitory computer-readable storage medium for use by or in connection with an instruction execution system, apparatus, or device, such as a computer-based system, processor-containing system, or other system that can fetch the instructions from the instruction execution system, apparatus, or device and execute the instructions.
- a “non-transitory computer-readable storage medium” can be any medium (excluding signals) that can contain or store the program for use by or in connection with the instruction execution system, apparatus, or device.
- the program storage 210 and/or memory 206 can be a non-transitory computer readable storage medium.
- the non-transitory computer readable storage medium (or multiple thereof) can have stored therein instructions, which when executed by the processor 204 or other processing circuitry, can cause the device including the computing electronic device 200 to perform one or more functions and methods of one or more examples of this disclosure.
- the computer-readable storage medium can include, but is not limited to, an electronic, magnetic, optical, electromagnetic, infrared, or semiconductor system, apparatus or device, a portable computer diskette (magnetic), a random access memory (RAM) (magnetic), a read-only memory (ROM) (magnetic), an erasable programmable read-only memory (EPROM) (magnetic), a portable optical disc such a CD, CD-R, CD-RW, DVD, DVD-R, or DVD-RW, or flash memory such as compact flash cards, secured digital cards, USB memory devices, memory sticks, and the like.
- the firmware can also be propagated within any transport medium for use by or in connection with an instruction execution system, apparatus, or device, such as a computer-based system, processor-containing system, or other system that can fetch the instructions from the instruction execution system, apparatus, or device and execute the instructions.
- a “transport medium” can be any medium that can communicate, propagate or transport the program for use by or in connection with the instruction execution system, apparatus, or device.
- the transport medium can include, but is not limited to, an electronic, magnetic, optical, electromagnetic or infrared wired or wireless propagation medium.
- the power source 208 can be implemented with any device capable of providing energy to the electronic device 200 .
- the power source 208 can include one or more batteries or rechargeable batteries.
- the power source 208 can include a power connector or power cord that connects the electronic device 200 to another power source, such as a wall outlet.
- the memory 206 can store electronic data that can be used by electronic device 200 .
- memory 206 can store electrical data or content such as, for example, audio and video files, documents and applications, device settings and user preferences, timing signals, control signals, and data structures or databases.
- the memory 206 can include any type of memory.
- the memory 206 can include random access memory, read-only memory, Flash memory, removable memory, other types of storage elements, or combinations of such memory types.
- the dual heat flux sensor 214 can measure voltage associated with a thermopile that is directly proportional to a temperature gradient and/or heat flux.
- the absolute temperature sensor 216 can measure temperature at given locations (e.g., top surface of outer thermopile, bottom surface of outer thermopile, top surface of inner thermopile, bottom surface of inner thermopile).
- the electronic device 200 can include sensing device(s) that can include sensors circuitry configured to sense one or more types of parameters, such as but not limited to, vibration; light; touch; force; heat; movement; relative motion; biometric data (e.g., biological parameters) of a user; air quality; proximity; position; connectedness; and so on.
- the sensing device(s) can include an image sensor such as an outward facing camera, a radiofrequency sensor (and/or transmitter), an infrared sensor (and/or transmitter), a magnetic sensor (and/or generator) (e.g., a magnetometer), an ultrasonic sensor (and/or transmitter), and/or an inertial measurement unit.
- the sensing device(s) can further include other sensor(s) including a force sensor, a heat sensor, a position sensor, a light or optical sensor, an accelerometer, a pressure transducer, a gyroscope, an acoustic sensor, a health monitoring sensor, and/or an air quality sensor, among other possibilities.
- the one or more sensors of the sensing device(s) can utilize any suitable sensing technology, including, but not limited to, interferometric, magnetic, capacitive, ultrasonic, resistive, optical, acoustic, piezoelectric, or thermal technologies.
- Wireless communication circuitry 202 can transmit or receive data from another electronic device. Although wireless communication circuitry 202 is illustrated and described, it is understood that other wired communication interfaces may be used. In some examples, the wireless and/or wired communications interfaces can include, but are not limited to, cellular, Bluetooth, and/or Wi-Fi communications interfaces. Although not shown, the electronic device 200 can also include other input/output mechanisms including one or more touch sensing input surfaces, a crown, one or more physical buttons, one or more microphones or speakers, one or more ports such as a microphone port, and/or a keyboard.
- FIG. 2 is only one example architecture of the electronic device 200 and that the device could have more or fewer components than shown, or a different configuration of components.
- the various components shown in FIG. 2 can be implemented in hardware, software, firmware, or any combination thereof, including one or more signal processing and/or application specific integrated circuits.
- an electronic device can simultaneously determine thermal resistance of skin and internal body temperature.
- FIG. 3 illustrates wearable device 300 configured to measure thermal resistance of skin (e.g., R wrist ) 312 and internal body temperature 306 .
- the wearable device 300 can correspond to a device 150 of FIG. 1 E (or more generally can correspond to any of the electronic devices illustrated by FIGS. 1 A- 1 E ).
- Wearable device 300 can include a housing 301 secured to a user via a strap or any other suitable fastener (e.g., corresponding to strap 154 ).
- the wearable device 300 can be secured to a user (e.g., exposed skin on the user's body).
- the wearable device 300 can correspond to a watch, a fitness tracker, or any other device (e.g., optionally used to measure physiological signals associated with the user).
- the wearable device 300 can attach to the user around the wrist (e.g., corresponding to layer of skin at a user's wrist 310 ), head, over the eyes, or on any exposed surface of the body that is suitable for measuring physiological signals (e.g., internal body temperature 306 ) associated with the user.
- the wearable device 300 can include a front face 303 , the housing 301 and a back face 305 .
- the front face 303 is sometimes referred to herein as the “front crystal” of the wearable device 300
- the back face 305 is sometimes referred to herein as the “back crystal” of the wearable device 300 .
- the front face 303 and back face 305 generally refer to a substrate such as glass, plastic, resin, gel, or crystal.
- the front face 303 and the back face 305 (also referred to as a rear face) can protect internal components of the wearable device 300 , but also allow for optical transmission from a display screen (e.g., touch screen) and/or optical sensors.
- the temperature sensing system within the wearable device 300 can be used to measure temperatures associated with a touch screen located at the front face 303 .
- the temperature sensing system can be configured to measure the temperature at a location or region inside wearable device 300 (e.g., optionally closer to the front face 303 ).
- the temperature sensing system can be used to measure the temperature outside of wearable device 300 , such as the temperature of air contacting the front face 303 , or the temperature of other objects at least partially in contact with, or overlapping the front face 303 , as described in FIG. 4 .
- the temperature sensing system within the wearable device 300 can be used to measure temperatures associated with an optical system located at the back face 305 .
- the temperature sensing system can be configured to measure the temperature at a location or region inside the wearable device 300 (e.g., optionally closer to the back face 305 ).
- the temperature sensing system can be used to measure the temperature outside of the wearable device 300 , such as the temperature of air contacting back face as described in FIG. 4 , or the temperature of other objects at least partially in contact with, or overlapping, back face (e.g., skin temperature at the wrist).
- the temperature sensing system can be used to measure the temperature at any location within wearable device 300 , as well as the temperature of objects outside wearable device 300 (e.g., the air surrounding wearable device as described in FIG. 4 ), or objects at least partially in contact with the front face 303 , the back face 305 , or the housing 301 ).
- a sensing glass, a printed circuit board (PCB), and the like can be disposed inside the housing 301 .
- the sensing glass or the printed circuit board (PCB) can be located inside the wearable device 300 , at the front face 303 (sometimes referred to as a “front crystal”).
- the printed circuit board (PCB) can include optical sensors configured to emit light and detect light through the front face 303 .
- the sensing glass or the printed circuit board (PCB) can be used to implement a touch sensor panel, display or touch screen (e.g., touch screen 152 ) disposed below the front face 303 .
- the sensing glass or the printed circuit board can include a processor (e.g., corresponding to processor 204 ), program storage (e.g., corresponding to program storage 210 ), optionally a touch and display controller, and/or temperature sensing devices (e.g., thermopiles of the dual heat flux sensor 214 , absolute temperature sensor 216 ).
- the sensing glass or the printed circuit board (PCB) can additionally or alternatively include one or more discrete absolute temperature sensors.
- the sensing glass or the printed circuit board (PCB) can be located inside the wearable device 300 , at the back face 305 (sometimes referred to as a “back crystal”).
- the printed circuit board (PCB) can include optical sensors configured to emit light and detect light through the back face. It should be understood that the number of sensing glass layers or printed circuit boards (PCBs), placement of sensing glass or the printed circuit boards PCBs, and distribution of components within the wearable device 300 is non-limiting.
- measurements of internal body temperature (T inner ) 306 can be susceptible to error from variances in thermal resistance of skin (e.g., person-to-person variations in skin properties such as fat tissue corresponding to R wrist 312 ).
- the sensing glass or the printed circuit board of the wearable device 300 can include thermopile(s) (e.g., inner and outer thermopiles). Each of the thermopile(s) can generate a temperature differential or gradient measurement between a bottom surface of the sensing glass or printed circuit board (PCB) and a top surface of the sensing glass or printed circuit board (e.g., when through-hole vias are used to form the thermopile(s)).
- PCB printed circuit board
- the inner thermopile and the outer thermopile can have different heat paths (e.g., temperature gradients). Temperature gradient measurements of the thermopiles (e.g., inner thermopile, outer thermopile) can be used for determining heat flux through a user wrist's (Q wrist ) 308 .
- the temperature sensing system can simultaneously measure the thermal resistance of skin, such as resistance associated with fat tissue of user's wrist (e.g., R wrist ) 312 , and the internal body temperature (T inner ) 306 of a user.
- processing circuitry of the temperature sensing system and/or the wearable device 300 can simultaneously measure the thermal resistance of skin (e.g., R wrist ) 312 and the internal body temperature (T inner ) 306 of a user.
- a temperature sensing system that includes at least inner and outer thermopiles can be used to accurately determine the thermal resistance of skin (e.g., R wrist ) 312 and internal body temperature (T inner ) 306 of the user.
- the wearable device 300 and/or the temperature sensing system can include any suitable number and arrangement of absolute temperature sensors.
- An absolute temperature sensor placed at the front crystal of the wearable device 300 can measure temperature at the front crystal (T fc ) 314
- an absolute temperature sensor temperature placed at the back crystal of the wearable device 300 can measure temperature at the back crystal (T bc ) 304 .
- an electronic device e.g., wearable device
- FIG. 4 illustrates wearable device 400 configured to measure thermal resistance of air (h) 406 ambient temperature (T ⁇ ) 408 .
- the wearable device 400 corresponds to the wearable device 300 described in FIG. 3 , thereby includes a housing 401 , a front face 403 , and a back face 405 .
- sensing glass or the printed circuit board (PCB) of the wearable device 400 can include thermopile(s) (e.g., inner and outer thermopiles).
- thermopile(s) e.g., inner and outer thermopiles
- Each of the thermopile(s) can generate a temperature differential or gradient measurement between a bottom surface of the sensing glass or printed circuit board (PCB) and a top surface of the sensing glass or printed circuit board (e.g., when through-hole vias are used to form the thermopile(s)).
- the inner thermopile and the outer thermopile can have different heat paths (e.g., temperature gradients).
- Temperature gradient measurements of the thermopiles e.g., inner thermopile, outer thermopile
- the temperature sensing system can simultaneously measure the thermal resistance of air (h) 406 and the ambient temperature (T ⁇ ) 408 .
- processing circuitry of the temperature sensing system and/or the wearable device 400 can simultaneously measure the thermal resistance of air (h) 406 and the ambient temperature (T ⁇ ) 408 .
- a temperature sensing system that includes at least inner and outer thermopiles can be used to accurately determine the thermal resistance of air (h) 406 and the ambient temperature (T ⁇ ) 408 .
- the wearable device 400 and/or the temperature sensing system can include any suitable number and arrangement of absolute temperature sensors.
- An absolute temperature sensor placed at the front crystal of the wearable device 400 e.g., watch
- an absolute temperature sensor temperature placed at the back crystal of the wearable device 300 e.g., watch
- FIG. 5 illustrates a cross-section of an example temperature sensing system according to examples of the disclosure.
- a temperature sensing system (e.g., dual heat flux sensor) 500 can include at least a block (e.g., housing) 508 and sensing glass 504 (also referred to as a first glass substrate) embedded with an inner thermopile 510 and an outer thermopile 512 .
- the sensing glass 504 can be disposed within or coupled to the block 508 .
- the temperature sensing system can also include passivation layer 502 (also referred to as a passivation glass or a second glass substrate, when the passivation layer material is glass), a cavity 506 disposed within the block 508 , thermal insulation layer(s) 520 , absolute temperature sensor(s), and/or additional thermopiles. It should be noted that the number and distribution of components within the temperature sensing system 500 is non-limiting.
- the sensing glass 504 can include the inner thermopile 510 and the outer thermopile 512 .
- the inner thermopile 510 and the outer thermopile 512 separately measure heat flux, which is used to determine internal body temperature and/or ambient temperature.
- a temperature gradient associated with the inner thermopile 510 (T 3 ⁇ T 1 ) can be different than the temperature gradient associated with the outer thermopile 512 (T 4 ⁇ T 2 ).
- T 3 ⁇ T 1 represents a temperature gradient between a top surface of the inner thermopile 510 and a bottom surface of the inner thermopile 510 .
- T 4 ⁇ T 2 represents a temperature gradient between a top surface of the outer thermopile 512 and a bottom surface of the outer thermopile 512 .
- the temperature sensing system 500 can include any number of absolute temperature sensors.
- the temperature sensing system 500 can include a first absolute temperature located near T 3 to measure temperature at a top surface of the inner thermopile 510 , a second absolute temperature located near T 1 to measure temperature at a bottom surface of the inner thermopile 510 , a third absolute temperature located near T 4 to measure temperature at a top surface of the outer thermopile 512 , and a fourth absolute temperature located near T 2 to measure temperature at a bottom surface of the outer thermopile 512 .
- the inner thermopile 510 has a diameter between 0.01-10 millimeters.
- the inner thermopile 510 has a diameter of 0.01, 0.003, 0.055, 0.1, 0.5, 1, or 1.5 millimeters.
- the outer thermopile 512 has a diameter between 0.05-15 millimeters.
- the outer thermopile 512 has a diameter of 0.05, 0.5, 1 3, 5, 8 or 10 millimeters.
- the inner thermopile 510 and the outer thermopile 512 can include through hole thermopiles, which traverse the sensing glass 504 from top to bottom.
- the inner thermopile 510 and the outer thermopile 512 can include blind thermopiles, buried thermopiles, and/or micro-thermopiles.
- the height 514 of the inner thermopile 510 and the height 516 of the outer thermopile 512 can be between 0.1-5 millimeters. In some examples, height 514 and height 516 can be 0.1, 0.5, 1. 5, 2, 3, or 5 millimeters. It should be appreciated that height 514 of the inner thermopile 510 and height 516 of the outer thermopile 512 are shown to be equal. By having no step up or height difference between the inner thermopile 510 and the outer thermopile 512 , the temperature sensing system can be thinner, more compact, less expensive to manufacture, and easier to integrate into compact housings (e.g., watch). It is understood that, in some examples, there can be a small height differential within the manufacturing tolerance.
- passivation layer 502 can be disposed above the sensing glass 504 (e.g., near the front crystal of a wearable device).
- the passivation layer 502 can prevent electrical shorting between the wearable device (e.g., including the temperature sensing system 500 ) and the environment.
- passivation layer 502 can also be disposed near the back crystal of the wearable device.
- the passivation layer 502 includes epoxy, glass, a polymer material, a ceramic material (e.g., silicon nitride), a composite material, and so forth.
- the passivation layer 502 has a height between 100 nanometers and 1 millimeter.
- the passivation layer 502 has a height of 100 nanometers, 500 nanometers, 1000 nanometers, 10 microns, 100 microns, or 1000 microns.
- lateral (e.g., vertical) edge(s) of the temperature sensing system include thermal insulation layer(s) 520 .
- the thermal insulation layer(s) 520 can be external to the block 508 .
- the thermal insulation layer(s) 520 are disposed a threshold distance (0.5, 1, 2, 3, 5, etc. millimeters) from the outer thermopile 512 .
- the thermal insulation layer(s) 520 can include epoxy, glass, plastic, and so forth to prevent electrical shorting.
- the thermal insulation layers(s) 520 can have a diameter between 100 nanometers and 1 millimeter. In some examples, the thermal insulation layers(s) 520 can have a diameter of 100 nanometers, 500 nanometers, 1000 nanometers, 10 microns, 100 microns, or 1000 microns.
- the cavity 506 can be disposed below the sensing glass 504 and within the block 508 .
- the cavity 506 can include an air cavity or a vacuum cavity.
- a glass layer 506 that is different from the sensing glass 504 and/or the passivation layer 502 can be disposed below the sensing glass 504 and within the block 508 .
- the cavity or glass layer 506 can have a diameter 522 between 0.5 to 6 millimeters.
- the cavity or glass layer 506 can have a diameter of 0.5, 1, 1,5, 2, 3, 4, 5, or 6 millimeters.
- the cavity or glass layer 506 can have a height between 0.1 to 3 millimeters.
- the cavity or glass layer 506 can have a height 524 of 0.1, 0.5, 1, 1.5, 2, 2.5, or 3 millimeters.
- a diameter 528 of the temperature sensing system 500 is at least 1.5 times greater than the diameter of the outer thermopile 512 .
- the diameter 528 of the temperature sensing system 500 can be between 6 and 15 millimeters.
- the diameter 528 of the temperature sensing system 500 can be between 9 and 12 millimeters.
- a height 526 of the temperature sensing system 500 can be between 3.5 and 5 millimeters.
- a 526 of the temperature sensing system 500 is less than 4 millimeters. It is understood that the diameters and heights or ranges of diameters and heights can be different than those above, depending on the size requirements of the temperature sensing system.
- the temperature sensing system 500 can include any number and arrangement of absolute temperature sensors and thermopiles.
- a temperature gradient e.g., heat flux, T 3 ⁇ T 1
- a temperature gradient e.g., heat flux, T 4 ⁇ T 2
- a lateral temperature difference 518 T 4 ⁇ T 3
- T 2 ⁇ T 1 at least one absolute temperature
- the temperature gradient (e.g., heat flux) associated with the inner thermopile 510 can also be used to determine thermal resistance of air and ambient temperature.
- the lateral temperature difference 518 can be measured using an additional surface thermopile disposed between the inner thermopile and the outer thermopile (e.g., along a surface of sensing glass 504 ).
- a first absolute temperature sensor can be disposed at a bottom surface of the inner thermopile 510 to measure T 1 and a second absolute temperature sensor can be disposed at a bottom surface of the outer thermopile 512 to measure T 2 . Based on a temperature associated with the bottom surface of the inner thermopile 510 , and a temperature associated with the bottom surface of the outer thermopile 512 , lateral temperature difference 518 (e.g., T 1 ⁇ T 2 ) can be determined.
- a third absolute temperature sensor can be disposed at a top surface of the inner thermopile 510 to measure T 3 and a fourth absolute temperature sensor can be disposed at a bottom surface of the outer thermopile 512 to measure T 4 .
- lateral temperature difference 518 (e.g., T 3 ⁇ T 4 ) can be determined.
- the temperature gradient associated with the inner thermopile 510 , the temperature gradient associated with the outer thermopile 512 , the lateral temperature difference 518 , and at least one absolute temperature from T 1 , T 2 , T 3 , or T 4 can be used to determine internal body temperature and/or ambient temperature.
- At least four absolute temperatures can be used to determine internal body temperature and/or ambient temperature.
- T 1 can represent a location of a first absolute temperature sensor
- T 2 can represent a location a second absolute temperature sensor
- T 3 can represent a location of a third absolute temperature sensor
- T 4 can represent a location of a fourth absolute temperature sensor can form a concentric ring structure.
- the first absolute temperature sensor, the second absolute temperature sensor, the third absolute temperature sensor, and the fourth absolute temperature sensor can include vapor deposited, nickel-chromium resistance temperature detectors (NiCr RTDs).
- the temperature gradient associated with the inner thermopile 510 , the temperature gradient associated with the outer thermopile 512 , and least two absolute temperatures can be used to determine internal body temperature and/or ambient temperature.
- any suitable combination of the temperature gradient associated with the inner thermopile 510 , the temperature gradient associated with the outer thermopile 512 , the lateral temperature difference 518 , and one or more absolute temperatures can be used to determine internal body temperature and/or ambient temperature.
- FIG. 6 illustrates a cross-sectional side view of an example temperature sensing system according to examples of the disclosure.
- the temperature sensing system 600 can include a layer of sensing glass 604 or a printed circuit board (PCB) embedded with inner thermopile 610 and outer thermopile 612 .
- Temperature gradients associated with inner thermopile 610 and outer thermopile 612 can be used to determine thermal resistance of skin (R wrist ) and internal body temperature (T inner ). Additionally or alternatively, temperature gradients associated with inner thermopile 610 and outer thermopile 612 can be used to determine thermal resistance of air (h) and ambient temperature (T ⁇ ).
- system equations [1] and/or [2] can be used.
- equation [1] can be used to determine the thermal resistance of skin and/or internal body temperature.
- equation [1] can be used to determine heat conduction associated with the inner thermopile 610 , where R path can represent a first heat path from subsurface tissue of a user's body (e.g., resistance of fat tissue associated with the user's wrist) to the user's wrist (e.g., resistance of skin at the user's wrist).
- ⁇ T can represent the change in temperature (e.g., temperature gradient) associated with the inner thermopile 610 .
- equation [1] can be used to determine heat conduction associated with the outer thermopile 612 , where R path can represent a second heat path from the user's wrist (e.g., resistance of skin at a user's wrist) to a user's watch (e.g., resistance of the watch).
- ⁇ T can represent the change in temperature (e.g., temperature gradient) of the outer thermopile 612 .
- equation [1] and/or equation [2] can be used to determine thermal resistance of air (h) and/or ambient temperature.
- equation [1] can be used to determine heat conduction associated with the inner thermopile 610 , where R path can represent a third heat path from the user's wrist (e.g., resistance of skin at the user's wrist) to the user's watch (e.g., resistance of the watch).
- equation [1] can be used to determine heat conduction associated with the outer thermopile 612 , where R path can represent a fourth heat path from the user's watch (e.g., resistance of the watch) to the ambient environment (e.g., resistance associated with wind speed and humidity).
- equation [1] using the third and fourth heath paths described above can be used to determine ambient temperature.
- both equations [1] and [2] can be used to determine ambient temperature.
- only equation [2] can be used to determine the ambient temperature.
- equation [2] can be used to determine heat convection associated with the inner thermopile 610 , where A surface can represent surface area of the inner thermopile 610 exposed to air.
- equation [2] can be used to determine heat convection associated with the outer thermopile 612 , where A surface can represent surface area of the outer thermopile 612 exposed to air.
- Equations [3] and [ 4 ] represent equation [1] using the temperature gradient and thermal resistance for each path illustrated in FIGS. 5 - 6 (e.g., first heat path associated with the inner thermopile and second heat path associated with the outer thermopile.
- Equation [3] represents heat flux (e.g., Q 1 ) associated with the inner thermopile 610 .
- T 3 ⁇ T 1 represents a temperature gradient between a top surface of the inner thermopile 610 and a bottom surface of the inner thermopile 610 .
- R 1-3 represents thermal resistance between the top surface of the inner thermopile 610 and the bottom surface of the inner thermopile 610 .
- Equation [4] represents heat flux (e.g., Q 2 ) associated with the outer thermopile 612 .
- T 4 ⁇ T 2 represents a temperature gradient between a top surface of the outer thermopile 612 and a bottom surface of the outer thermopile 612 .
- R 2-4 represents thermal resistance between the top surface of the outer thermopile 612 and the bottom surface of the outer thermopile 612 .
- internal body temperature (T inner ) can be determined using the following equation:
- thermal resistance of skin (R wrist ) and internal body temperature (T inner ) can be determined based at least on the temperature gradient (T 3 ⁇ T 1 ) associated with the inner thermopile 610 , the temperature gradient (T 4 ⁇ T 2 ) associated with the outer thermopile 612 , a lateral temperature difference between the inner thermopile 610 and the outer thermopile 612 , and an absolute temperature.
- Equations [6] and [7] represent equations [1]and [2] using the temperature gradient and thermal resistance for each path illustrated in FIGS. 5 - 6 .
- Equation [6] represents heat flux (e.g., Q 1 ) associated with the inner thermopile 610 .
- the heat flux (e.g., Q 1 ) in equation 6 is equal to
- T 1 ⁇ T 3 represents a temperature gradient between a top surface of the inner thermopile 610 and a bottom surface of the inner thermopile 610 .
- R 1-3 represents thermal resistance between the top surface of the inner thermopile 610 and the bottom surface of the inner thermopile 610 .
- a 3 represents the surface area of a heat path associated with the inner thermopile 610 exposed to the ambient environment.
- Equation [7] represents heat flux (e.g., Q 2 ) associated with the outer thermopile 612 .
- the heat flux (e.g., Q 2 ) in equation 7 is equal to
- T 2 ⁇ T 4 represents a temperature gradient between a top surface of the outer thermopile 612 and a bottom surface of the outer thermopile 612 .
- R 2-4 represents thermal resistance between the top surface of the outer thermopile 612 and the bottom surface of the outer thermopile 612 .
- a 4 represents the surface area of a heat path associated with the outer thermopile 610 exposed to the ambient environment.
- ambient temperature (T ⁇ ) can be determined using the following equation:
- thermal resistance of air (h) and ambient temperature (T ⁇ ) can be determined based at least on the temperature gradient (T 1 ⁇ T 3 ) associated with the inner thermopile 610 , the temperature gradient (T 2 ⁇ T 4 ) associated with the outer thermopile 612 , the lateral temperature difference between the inner thermopile 610 and the outer thermopile 612 , and an absolute temperature.
- FIG. 7 A illustrates an example temperature sensing system 700 including inner thermopile 702 and outer thermopile 704 forming concentric shapes (e.g., concentric cylinders, concentric polygonal shapes, concentric geometric shapes, concentric non-geometric shapes) according to examples of the disclosure.
- concentric shapes e.g., concentric cylinders, concentric polygonal shapes, concentric geometric shapes, concentric non-geometric shapes
- the temperature sensing system can be thinner, more compact, less expensive to manufacture, and easier to integrate into compact housings (e.g., watch, wearables, portables, etc.).
- FIG. 7 B illustrates a top view of an example temperature sensing system 750 that includes an additional thermopile 752 disposed between an inner thermopile (e.g., corresponding to inner thermopile 702 ) and an outer thermopile (e.g., corresponding to outer thermopile 704 ).
- the additional thermopile 752 can measure a lateral temperature gradient (T 3 ⁇ T 4 ) between a top surface of the inner thermopile and a top surface of the outer thermopile.
- the additional thermopile 752 can measure a lateral temperature gradient (T 1 ⁇ T 2 ) between a bottom surface of the inner thermopile and a bottom surface of the outer thermopile.
- each thermopile can be formed from a series of thermocouples.
- each thermocouple includes at least two dissimilar conductive materials (e.g., copper and constantan).
- FIG. 8 A illustrates a schematic illustration of an example thermopile 810 (e.g., inner thermopile, outer thermopile) formed from a series of thermocouples 808 according to examples of the disclosure.
- an inner thermopile e.g., corresponding to inner thermopile 702
- the inner thermopile can include a first set of dissimilar conductive materials (e.g., metal fillings) that are similar to second set of dissimilar conductive materials of the outer thermopile.
- each of the first and second set of dissimilar conductive materials can include any number of dissimilar metals or alloys (e.g., 2, 3, 4, or 5 different metals).
- Non-limiting examples of the first set of dissimilar conductive materials includes copper and constantan; chromel and constantan; chromium and constantan; nickel, copper, and chromium; and copper and chromium.
- Non-limiting examples of the second set of dissimilar conductive materials includes copper and constantan; chromel and constantan; chromium and constantan; nickel, copper, and chromium; and copper and chromium.
- via holes can be formed through a layer of the sensing glass, and filled with respective vias (e.g., respective conductive materials).
- the inner thermopile and the outer thermopile can be embedded within a printed circuit board (PCB).
- PCB printed circuit board
- various printed circuit board (PCB) processing methods, using with various materials (e.g., high volume production processes) can be used to create the vias.
- Deposition methods for forming the different layers include printing, dispensing material into holes/vias, and vacuum printing.
- a first via 800 can be filled with copper, copper particles suspended in epoxy, or copper-coated particles suspended in epoxy (e.g., according to a “via fill” manufacturing process). Additionally or alternatively, the first via 800 can be filled with aluminum, gold, carbon ink, or any suitable metal or alloy.
- a second via 802 can be filled with such as constantan, constantan particles suspended in epoxy, or constantan-coated particles suspended in epoxy. Additionally or alternatively, the second via 802 can be filled with aluminum, gold, carbon ink, or any suitable metal or alloy.
- the inner thermopile and the outer thermopile 704 are embedded within the printed circuit board (PCB), then the two vias can be then connected via a conductive trace 804 .
- the conductive trace 804 can include copper, aluminum, gold, carbon ink, or any suitable metal or alloy.
- the two vias 800 and 802 can be then connected using patterning at a copper layer of the printed circuit board (PCB), such as a copper connector 804 . Connecting the first and second vias 800 and 802 using the conducive trace or the copper connecter 804 forms a thermocouple, when the metal filled in the first via 800 has a different Seebeck coefficient than the metal filled in the second via 802 .
- thermopile 810 formed from the series combination of such vias measures heat flux, or the temperature differential/gradient, across the height of the sensing glass or the printed circuit board (PCB).
- Each pair of connected vias, such as the first and second vias 800 and 802 , with dissimilar conductors (e.g., metals) forms a thermocouple 808 , and connecting such pairs of connected vias forms a thermopile 810 embedded within the sensing glass or the printed circuit board (PCB).
- each thermocouple 808 can be two-dimensional, and a series of thermocouples 808 can form a multidimensional (e.g., three-dimensional) thermopile 810 .
- the thermopile 810 can output a voltage measurement 806 that is directly proportional to a temperature gradient and/or heat flux, which can help determine internal body temperature and/or ambient temperature.
- FIG. 8 B illustrates a top view of example inner thermopile 850 and outer thermopile 852 according to examples of the disclosure.
- the inner thermopile 850 can include a cluster of thermocouples (e.g., forming a “solid” cylindrical shape, a rectangular shape, a geometric shape, or a non-geometric shape).
- the cluster of thermocouples of the inner thermopile 850 can be concentric or non-concentric.
- the inner thermopile 850 can include any number of thermocouple rows and any number of thermocouple columns.
- the outer thermopile 852 can include a cluster of thermocouples (e.g., forming a “hollow” cylindrical shape, a rectangular shape, a geometric shape, or a non-geometric shape) can include any number of thermocouple rows, such as 6 rows of thermocouples as illustrated in FIG. 8 B , and any number of thermocouple columns.
- the cluster of thermocouples of the outer thermopile 852 can be concentric in relation to the cluster of thermocouples of the inner thermopiles.
- the cluster of thermocouples of the outer thermopile 852 can be non-concentric.
- the temperature sensing system (e.g., dual heat flux sensor) described in FIGS. 2 - 7 is disposed in the wearable device (e.g., watch) such that the temperature sensing system measures a vertical gradient (e.g., parallel to a line from the front face to the rear face).
- the temperature sensing system is disposed in the wearable device such that the temperature sensing system measures a lateral gradient (e.g., perpendicular to a line from the front face to the rear face).
- more than one temperature sensing systems can be integrated into a wearable device, such as a first temperature sensing system that measures a vertical gradient and a second temperature sensing system that measures a lateral gradient.
- the use of one or more temperature sensing systems measuring one or more lateral gradients can allows the wearable device to account for variances in thermal resistance of skin (e.g., skin 902 in FIGS. 9 A- 9 B ) and/or air (e.g., variances in thermal resistance due to variance in amount of fat tissue, wind speed, humidity) when determining ambient temperature and/or internal body temperature.
- a wearable device that includes at least two temperature sensing systems improves accuracy of temperature and/or internal body temperature measurements.
- a wearable device that includes a first temperature sensing system disposed at or near (within a threshold distance of) a center of the wearable device (optionally near a front face or rear face) and a second temperature sensing system disposed at or near (within a threshold distance of) a side of the wearable device to measure a lateral gradient can improve accuracy of temperature and/or internal body temperature measurements.
- FIG. 9 A illustrates a top view of wearable device (e.g., watch) 900 that includes a first temperature sensing system 904 disposed at or near a front face of the wearable device 900 (e.g., approximately at the center of the front face) and one or more second temperature sensing systems 906 A, 906 B, 906 C, or 906 D disposed at or near a side surface of the wearable device 900 .
- the first temperature sensing system includes a dual heat flux sensor to measure a vertical gradient of the wearable device 900 (e.g., corresponding to temperature sensing system 500 ).
- the second temperature sensing system includes a dual heat flux sensor to measure a lateral gradient at a lateral surface of the wearable device 900 (e.g., corresponding to temperature sensing system 500 but oriented laterally in the wearable device 900 ).
- the second temperature sensing system includes a thermopile and an absolute temperature sensor to measure a lateral gradient at a lateral surface of the wearable device 900 .
- the second temperature sensing system includes two absolute temperature sensors to measure a lateral gradient at a lateral surface of the wearable device 900 .
- structures of the wearable device 900 including one or more temperature sensing systems are further described with respect to the cross-section of the wearable device 900 as shown in FIG. 9 B .
- a single temperature sensing system (e.g., first temperature sensing system 904 in FIG. 9 A ) is disposed at a face of the wearable device 900 and a single temperature sensing (e.g., a second temperature sensing system 906 A, 906 B, 906 C, or 906 D in FIG. 9 A ) is disposed at any side surface of the wearable device. As shown in FIG. 9 A
- the first temperature sensing system 904 is disposed at a central position on the front face of the wearable device 900 (e.g., at or near the center of a plane parallel to a watch face), and the second temperature sensing system 906 A, 906 B, 906 C, or 906 D is disposed at a central position on a respective side surface of the wearable device 900 (e.g., at or near a center of a side of a plane parallel to a watch face). It is understood that the placement of temperature sensing systems in FIG. 9 A is a non-limiting example.
- the first temperature sensing system 904 is disposed at any suitable position (e.g., off-center of the plane of the face), and the second temperature sensing system 906 A, 906 B, 906 C, or 906 D is disposed at any suitable position (e.g., off-center of a side of the plane of the face).
- multiple temperature sensing systems measuring lateral gradients are disposed at multiple sides of the wearable device 900 .
- temperature sensing system 906 A is optionally disposed at or near a first side of the wearable device 900
- temperature sensing system 906 B is optionally disposed at or near a second side of the wearable device 900
- temperature sensing system 906 C is optionally disposed at or near a third side of the wearable device 900
- temperature sensing system 906 D is optionally disposed at or near a fourth side of the wearable device 900 .
- Each of the four temperature sensing systems 906 A- 906 D can measure a lateral temperature gradient for a respective side of the wearable device.
- at least one additional temperature sensing system measuring a lateral gradient is disposed at a respective side of the wearable device 900 .
- FIG. 9 B illustrates a cross-sectional side view of wearable device (e.g., watch) 900 that includes a first temperature sensing system 904 disposed on a front face of the wearable device 900 and a second temperature sensing system 906 (e.g., corresponding to temperature sensing system 906 A in FIG. 9 A ) disposed at a representative side of the wearable device 900 .
- the second temperature sensing system 956 measures a lateral gradient corresponding to a difference between T 2 and T 4 .
- the second temperature sensing system 906 corresponds to the second temperature sensing system 906 A of FIG. 9 A .
- the wearable device 900 includes additional temperature sensing system(s) configured to measure additional lateral gradient(s).
- the additional temperature sensing system(s) can correspond to the second temperature sensing system 906 C of FIG. 9 A the details of which are not shown or repeated for brevity.
- FIG. 10 illustrates an example process 1000 for measuring internal temperature and/or ambient temperature according to some examples of the disclosure.
- the measuring of internal temperature and/or ambient temperature can include computing operations based on measured temperatures from one or more absolute temperature sensors and from one or more thermopiles.
- processing circuitry of an electronic device e.g., electronic device 200 , wearable device 150
- processing circuitry of an electronic device can receive a thermal gradient associated with an inner thermopile and a thermal gradient associated with the outer thermopile.
- Temperature gradient measurements of thermopiles e.g., inner thermopile, outer thermopile
- the processing circuitry can compute a thermal resistance of skin and internal body temperature based at least on the thermal gradient associated with the inner thermopile, the thermal gradient associated with the outer thermopile, a lateral temperature difference between the inner thermopile and the outer thermopile, and at least one absolute temperature (e.g., T 1 , T 2 , T 3 , or T 4 ). Further, the processing circuitry can compute a thermal resistance of air and ambient temperature based at least on the thermal gradient associated with the inner thermopile, the thermal gradient associated with the outer thermopile, a lateral temperature difference between the inner thermopile and the outer thermopile, and at least one absolute temperature (e.g., T 1 , T 2 , T 3 , or T 4 ).
- the processing circuitry can compute the lateral temperature difference between the inner thermopile and the outer thermopile using an additional thermopile between the inner thermopile and the outer thermopile and/or at least one absolute temperature sensor.
- the processing circuitry can display the internal body temperature and/or ambient temperature via a display (e.g., corresponding to touch screen 152 ) of the wearable device. It is understood that process 1000 illustrated in FIG. 10 is not limited to the operation as presented, but can include, fewer, additional, and/or simultaneous operations according to various examples.
- the electronic device can comprise a thermal sensing system.
- the thermal sensing system can comprise a sensing surface, where the sensing surface comprises an inner thermopile associated with a first heat path and an outer thermopile associated with a second heat path, where the inner thermopile is same in height as the outer thermopile, and where the inner thermopile and the outer thermopile form concentric geometries.
- the thermal sensing system can comprise a first absolute temperature configured to measure a first absolute temperature.
- the electronic device can comprise a processor communicatively coupled to the thermal sensing system and configured to compute an ambient temperature or body temperature using a first temperature gradient associated with the first heat path, a second temperature gradient associated with the second heat path, a lateral temperature difference between the inner thermopile and the outer thermopile, and the first absolute temperature.
- the processor can be configured to compute the ambient temperature or the body temperature using the first temperature gradient associated with the first heat path, the second temperature gradient associated with the second heat path, and at least two absolute temperatures.
- the first absolute temperate sensor can be configured to measure a first absolute temperature at a first surface of the inner thermopile.
- the thermal sensing system can comprise a second absolute temperate sensor configured to measure a second absolute temperature at a first surface of the outer thermopile.
- the processor can be configured to compute the ambient temperature or the body temperature using the first temperature gradient associated with the first heat path, a second temperature gradient associated with the second heat path, and at least two absolute temperatures. Additionally or alternatively to one or more of the examples disclosed above, in some examples, the processor can be configured to compute the lateral temperature difference between the inner thermopile and the outer thermopile using the first absolute temperature and the second absolute temperature.
- processor can be configured to compute the lateral temperature difference between the inner thermopile and the outer thermopile using a surface thermopile disposed between the inner thermopile and the outer thermopile. Additionally or alternatively to one or more of the examples disclosed above, in some examples, the processor can be configured to compute the ambient temperature using the first temperature gradient, the second temperature gradient, the lateral temperature difference between the inner thermopile and the outer thermopile, a first surface area of the first heat path exposed to the ambient temperature, a second surface area of the second heat path exposed to the ambient temperature, a first resistance associated with the first heath path, and a second resistance associated with the second heat path.
- the sensing surface can comprise glass or a printed circuit board.
- the inner thermopile can comprise a first set of metal fillings and the outer thermopile can comprise a second set of metal fillings different from the first set of metal fillings.
- the first set of metal fillings can comprise copper and constantan and the second set of metal fillings can comprise chromel and constantan.
- the thermal sensing system can comprise a passivation layer disposed on the sensing surface, and the passivation layer can comprise epoxy, silicon nitride, glass, a polymer material, a ceramic material, a composite material, or any combination thereof. Additionally or alternatively to one or more of the examples disclosed above, in some examples, the thermal sensing system can comprise a thermal insulation layer disposed a threshold distance from the outer thermopile. Additionally or alternatively to one or more of the examples disclosed above, in some examples, the concentric geometries can comprise concentric cylinders.
- Some examples of the disclosure are directed to a method of operating the system described herein or a non-transitory computer readable storage medium storing instructions configured to be executed by one or more processors of the system to cause the processor(s) to perform any of the above operations of the system.
- the dual heat flux sensor can comprise a sensing glass comprising an inner thermopile and an outer thermopile, where the inner thermopile and the outer thermopile are uniform in height and form concentric geometries.
- the dual heat flux sensor can comprise a plurality of vias in the sensing glass comprising a plurality of first vias from a first surface of the sensing glass to a second surface of the sensing glass and a plurality of second vias from the first surface of the sensing glass to the second surface of the sensing glass, where the inner thermopile is formed from a first set of conductive materials filling the plurality of first vias and the outer thermopile is formed from a second set of conductive materials filling the plurality of second vias.
- the dual heat flux sensor can comprise sensing circuitry configured to measure a temperature gradient associated with the inner thermopile and a second temperature gradient associated with the outer thermopile.
- the first set of conductive materials can be different than the second set of conductive materials.
- a diameter of the dual heat flux sensor can be at least 1.5 times greater than a diameter of the outer thermopile. Additionally or alternatively to one or more of the examples disclosed above, in some examples, a diameter of the dual heat flux sensor can be between 9 millimeters and 12 millimeters. Additionally or alternatively to one or more of the examples disclosed above, in some examples, a height of the dual heat flux sensor can be less than 4 millimeters.
- the dual heat flux sensor can comprise a housing coupled to the sensing glass, the housing can comprise a cavity disposed beneath the sensing glass, and the cavity can comprise air. Additionally or alternatively to one or more of the examples disclosed above, in some examples, the cavity can comprise a height between 0.5 millimeters and 2.5 millimeters. Additionally or alternatively to one or more of the examples disclosed above, in some examples, the dual heat flux sensor can comprise a glass layer different from the sensing glass and disposed beneath the sensing glass.
- Some examples of the disclosure are directed to a method of operating the system described herein or a non-transitory computer readable storage medium storing instructions configured to be executed by one or more processors of the system to cause the processor(s) to perform any of the above operations of the system.
- the method can include measuring one or more absolute temperatures; measuring a first thermal gradient associated with a first thermopile and a second thermal gradient associated with a second thermopile from a dual heat flux sensor; and computing an ambient temperature or an internal body temperature using the first thermal gradient, the second thermal gradient, a lateral temperature difference between the first thermopile and the second thermopile, the one or more absolute temperatures, or any combination thereof. Additionally or alternatively to one or more of the examples disclosed above, in some examples, the method can include computing the lateral temperature difference between the first thermopile and the second thermopile using a third thermopile disposed between the first thermopile and the second thermopile or the one or more absolute temperature sensors.
- the method can include outputting (e.g., displaying) an internal body temperature or ambient temperature.
- Some examples of the disclosure are directed to a non-transitory computer readable storage medium storing instructions configured to be executed by one or more processors of the system to cause the processor(s) to perform any of the above operations of the system.
- Some examples of the disclosure are directed to a non-transitory computer readable storage medium.
- the non-transitory computer readable storage medium storing instructions configured to be executed by one or more processors of the system to cause the processor(s) to: measure one or more absolute temperatures; measure a first thermal gradient associated with a first thermopile and a second thermal gradient associated with a second thermopile from a dual heat flux sensor; and compute an ambient temperature or an internal body temperature using the first thermal gradient, the second thermal gradient, a lateral temperature difference between the first thermopile and the second thermopile, the one or more absolute temperatures, or any combination thereof.
- the instructions when executed by one or more processors of the system, cause the processor(s) to: compute the lateral temperature difference between the first thermopile and the second thermopile using a third thermopile disposed between the first thermopile and the second thermopile or the one or more absolute temperature sensors. Additionally or alternatively to one or more of the examples disclosed above, in some examples, the instructions, when executed by one or more processors of the system, cause the processor(s) to: output (e.g., displaying) an internal body temperature or ambient temperature.
- the system can comprise a first absolute temperature sensor configured to measure a first absolute temperature at a first surface of an inner thermopile, a second absolute temperature sensor configured to measure a second absolute temperature at a first surface of an outer thermopile, a third absolute temperature sensor configured to measure a third absolute temperature at a second surface of the inner thermopile, and a fourth absolute temperature sensor configured to measure a fourth absolute temperature at a second surface of the outer thermopile.
- the system can comprise a processor communicatively coupled to the first absolute temperature sensor, the second absolute temperature sensor, the third absolute temperature sensor, and the fourth absolute temperature sensor and configured to compute an ambient temperature or an internal body temperature using the first absolute temperature, the second absolute temperature, the third absolute temperature, and the fourth absolute temperature.
- a processor communicatively coupled to the first absolute temperature sensor, the second absolute temperature sensor, the third absolute temperature sensor, and the fourth absolute temperature sensor and configured to compute an ambient temperature or an internal body temperature using the first absolute temperature, the second absolute temperature, the third absolute temperature, and the fourth absolute temperature.
- the system can comprise a first temperature sensing system configured to measure one or more vertical gradients and a second temperature sensing system configured to measure one or more lateral gradients.
- the first temperature sensing system includes a first dual heat flux sensor and/or a second dual heat flux sensor.
- the first dual heat flux sensor and/or the second dual heat flux sensor can correspond to any of the above described heat flux sensors.
- a respective dual heat flux sensor can comprise a sensing glass, a plurality of vias in the sensing glass, and sensing circuitry.
- the sensing glass can comprise an inner thermopile and an outer thermopile, where the inner thermopile and the outer thermopile are uniform in height and form concentric geometries.
- the plurality of vias in the sensing glass can comprise a plurality of first vias from a first surface of the sensing glass to a second surface of the sensing glass and a plurality of second vias from the first surface of the sensing glass to the second surface of the sensing glass, where the inner thermopile is formed from a first set of conductive materials filling the plurality of first vias and the outer thermopile is formed from a second set of conductive materials filling the plurality of second vias.
- Sensing circuitry can be configured to measure a temperature gradient associated with the inner thermopile and a second temperature gradient associated with the outer thermopile.
- the wearable device can comprise a temperature sensing system configured to measure one or more vertical gradients and one or more temperature sensing systems configured to measure one or more lateral gradients.
- one or more temperature sensing systems configured to measure one or more lateral gradients can include a first temperature sensing system configured to measure a first lateral gradient corresponding to a first side of the wearable device, a second temperature sensing system configured to measure a second lateral gradient corresponding to a second side of the wearable device, a third temperature sensing system configured to measure a third lateral gradient corresponding to a third side of the wearable device, and a fourth temperature sensing system configured to measure a fourth lateral gradient corresponding to a fourth side of the wearable device.
- the temperature sensing system configured to measure the vertical gradient and/or the one or more temperature sensing systems configured to measure the one or more lateral gradients can comprise a dual heat flux sensor corresponding to any of the above described heat flux sensors.
- a respective dual heat flux sensor can comprise a sensing glass, a plurality of vias in the sensing glass, and sensing circuitry.
- the sensing glass can comprise an inner thermopile and an outer thermopile, where the inner thermopile and the outer thermopile are uniform in height and form concentric geometries.
- the plurality of vias in the sensing glass can comprise a plurality of first vias from a first surface of the sensing glass to a second surface of the sensing glass and a plurality of second vias from the first surface of the sensing glass to the second surface of the sensing glass, where the inner thermopile is formed from a first set of conductive materials filling the plurality of first vias and the outer thermopile is formed from a second set of conductive materials filling the plurality of second vias.
- Sensing circuitry can be configured to measure a temperature gradient associated with the inner thermopile and a second temperature gradient associated with the outer thermopile.
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Abstract
A temperature sensing system includes absolute temperature sensor(s) and/or thermopiles that form concentric geometries and are uniform in height. In some examples, the temperature sensing system can determine internal body temperature and/or ambient temperature based at least on a thermal gradient associated with the inner thermopile, a thermal gradient associated with the outer thermopile, a lateral temperature difference between the inner and the outer thermopiles, and an absolute temperature. In some examples, the temperature sensing system can determine the internal body temperature and/or ambient temperature using at least four absolute temperature sensors forming a concentric structure.
Description
- This application claims the benefit of U.S. Provisional Application No. 63/371,820, filed Aug. 18, 2022, the content of which is incorporated herein by reference in its entirety for all purposes.
- This relates generally to temperature sensing systems and methods, and more particularly to temperature sensing systems and methods configured to measure internal body temperature and/or ambient temperature.
- Many types of sensing devices, such as temperature sensors, are presently available in electronic devices to measure temperature or heat conditions. Electronic devices can include a wearable device to measure internal body temperature. Electronic devices can also measure ambient temperature.
- An electronic device, such as a wearable device, can leverage temperature gradient measurements from thermopiles to measure temperature inside or outside the electronic device. As described herein, a thermopile can include a series-connected thermocouples and output a voltage measurement that is directly proportional to a temperature gradient and/or heat flux. For example, the electronic device can include a temperature sensing system that includes at least two thermopiles, which form concentric geometries. In some examples, the temperature sensing system can include a step up in height (e.g., a height differential) between the at least two thermopiles. However, the step up in height can complicate integration within compact housing (e.g., within a smart watch) due to space considerations for the temperature sensing system.
- In some examples, an improved temperature sensing system (e.g., dual heat flux sensor) that is compact in design by including thermopiles with uniform height (e.g., no step up between thermopiles) that form concentric geometries. In some examples, the improved temperature sensing system can include thermopiles with a height difference that is less than a threshold height difference (e.g., less than a difference of 10, 100, or 1000 microns in height between thermopiles). For example, the temperature sensing system can include a sensing surface (e.g., a glass layer) embedded with thermopiles, such as an inner thermopile (e.g., first thermopile) and an outer thermopile (e.g., second thermopile). A respective thermopile is associated with a respective heat path based on a temperature gradient between a top surface of the respective thermopile and a bottom surface of the respective thermopile. For example, the inner thermopile and the outer thermopile can have different heat paths (e.g., temperature gradients). Temperature gradient measurements of the thermopiles (e.g., inner thermopile, outer thermopile) can be used for determining heat flux (e.g., through an electronic device), surface temperature of objects contacting housing of the electronic device (e.g., ambient temperature), body temperature of a user wearing the electronic device, and so forth.
- Processing circuitry of the temperature sensing system or processing circuitry of the electronic device (e.g., wearable device) can leverage temperature gradient measurements of the thermopiles to account for variances in thermal resistance of skin and/or air (e.g., amount of fat tissue, wind speed, humidity) to accurately determine ambient temperature and/or internal body temperature. In some examples, to accurately determine thermal resistance of skin and internal body temperature and/or thermal resistance of air and ambient temperature, the processing circuitry of the temperature sensing system or the processing circuitry of the electronic device can use a temperature gradient of the inner thermopile, a temperature gradient of the outer thermopile, a lateral temperature difference between the inner thermopile and the outer thermopile, an absolute temperature of at least one surface of the inner thermopile or the outer thermopile, surface area of a heat path associated with the inner thermopile exposed to skin and/or air, surface area of a heat path associated with the outer thermopile exposed to skin and/or air, and so forth as inputs.
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FIGS. 1A-1E illustrate example systems that can include a touch screen according to examples of the disclosure. -
FIG. 2 illustrates a block diagram of an example electronic device according to examples of the disclosure. -
FIG. 3 illustrates an example wearable device that includes an example temperature sensing system to measure thermal resistance of skin and internal body temperature according to examples of the disclosure. -
FIG. 4 illustrates an example wearable device that includes an example temperature sensing system to measure thermal resistance of air and ambient temperature according to examples of the disclosure. -
FIG. 5 illustrates a cross-section of an example temperature sensing system according to examples of the disclosure. -
FIG. 6 illustrates a cross-sectional side view of an example temperature sensing system according to examples of the disclosure. -
FIG. 7A illustrates an example temperature sensing system including example inner and outer thermopiles forming concentric geometries according to examples of the disclosure. -
FIG. 7B illustrates a top view of an example temperature sensing system including an additional thermopile between the inner and outer thermopiles according to examples of the disclosure. -
FIG. 8A illustrates a schematic illustration of an example thermopile according to examples of the disclosure. -
FIG. 8B illustrates a top view of example inner and outer thermopiles according to examples of the disclosure. -
FIGS. 9A-9B illustrate a top view and a cross-sectional side view of an example wearable device that includes one or more temperature sensing systems according to examples of the disclosure. -
FIG. 10 illustrates a process for measuring internal temperature and/or ambient temperature according to some examples of the disclosure. - In the following description of examples, reference is made to the accompanying drawings which form a part hereof, and in which it is shown by way of illustration specific examples that can be practiced. It is to be understood that other examples can be used, and structural changes can be made without departing from the scope of the disclosed examples.
- This relates to a temperature sensing system (e.g., dual heat flux sensor) that is compact in design by including thermopiles that form concentric geometries and are uniform in height (e.g., no step up between thermopiles). In some examples, the temperature sensing system can include thermopiles with a height difference that is less than a threshold height difference (e.g., less than a difference of 10, 100, or 1000 microns in height between thermopiles). Processing circuitry of the temperature sensing system or processing circuitry of an electronic device (e.g., wearable device) can leverage temperature gradient measurements of the thermopiles to account for variances in thermal resistance of skin and/or air (e.g., amount of fat tissue, wind speed, humidity) to accurately determine ambient temperature and/or internal body temperature. In some examples, to accurately determine thermal resistance of skin and internal body temperature and/or thermal resistance of air and ambient temperature, the processing circuitry of the temperature sensing system or the processing circuitry of the electronic device can use a temperature gradient of the inner thermopile, a temperature gradient of the outer thermopile, a lateral temperature difference between the inner thermopile and the outer thermopile, an absolute temperature of at least one surface of the inner thermopile or the outer thermopile, surface area of a heat path associated with the inner thermopile exposed to skin and/or air, surface area of a heat path associated with the outer thermopile exposed to skin and/or air, and so forth as inputs. In some examples, rather than using temperature gradients from thermopiles, at least four absolute temperature sensors configured to measure respective absolute temperatures can be used to determine internal body temperature and/or ambient temperature. Accordingly, in some examples, the temperature sensing system can include four absolute temperature sensors forming a concentric ring structure. For example, a first absolute temperature sensor can measure a first absolute temperature at a first surface (e.g., bottom surface) of the inner thermopile, a second absolute temperature sensor can measure a second absolute temperature at a first surface (e.g., bottom surface) of the outer thermopile, a third absolute temperature sensor can measure a third absolute temperature at a second surface (e.g., top surface) of the inner thermopile, and a fourth absolute temperature sensor can measure a fourth absolute temperature at a second surface (e.g., top surface) of the outer thermopile. In some examples, using the first absolute temperature, the second absolute temperature, the third absolute temperature, and the fourth absolute temperature, the processing circuitry of the temperature sensing system or the processing circuitry of the electronic device can determine thermal resistance of skin and internal body temperature and/or thermal resistance of air and ambient temperature. In some examples, the processing circuitry of the temperature sensing system or the processing circuitry of the electronic device can determine thermal resistance of skin and internal body temperature and/or thermal resistance of air and ambient temperature using the temperature gradient of the inner thermopile, the temperature gradient of the outer thermopile, and least two absolute temperatures (e.g., first and second absolute temperatures, first and third absolute temperatures, third and fourth absolute temperatures, and so forth). In some examples, the processing circuitry of the temperature sensing system or the processing circuitry of the electronic device can determine thermal resistance of skin and internal body temperature and/or thermal resistance of air and ambient temperature using any suitable combination of the temperature gradient of the inner thermopile, the temperature gradient of the outer thermopile, the lateral temperature difference between the inner thermopile and the outer thermopile, and one or more absolute temperatures.
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FIGS. 1A-1E illustrate examples of systems, optionally with touch screens (e.g., capacitive touch screens), that can include an example temperature sensing system according to examples of the disclosure.FIG. 1A illustrates an examplemobile telephone 136 that optionally includes atouch screen 124 and can include an example temperature sensing system according to examples of the disclosure.FIG. 1B illustrates an exampledigital media player 140 that optionally includes atouch screen 126 and can include an example temperature sensing system according to examples of the disclosure.FIG. 1C illustrates an examplepersonal computer 144 that optionally includes atouch screen 128 and can include an example temperature sensing system according to examples of the disclosure.FIG. 1D illustrates an exampletablet computing device 148 that optionally includes atouch screen 130 and can include an example temperature sensing system according to examples of the disclosure.FIG. 1E illustrates an example wearable device 150 (e.g., a watch) that optionally includes atouch screen 152 and can include an example temperature sensing system according to examples of the disclosure.Wearable device 150 can be coupled to a user viastrap 154 or any other suitable fastener. It should be understood that the example devices illustrated inFIGS. 1A-1E are provided by way of example, and other devices can include an example temperature sensing system according to examples of the disclosure. Additionally, although the devices illustrated inFIGS. 1A-1E include touch screens, in some examples, the devices may have a non-touch sensitive display or no display. -
FIG. 2 illustrates a block diagram of an exampleelectronic device 200, according to examples of the disclosure. Theelectronic device 200 can measure and/or display ambient temperature and/or internal body temperature based on temperature measurements from the temperature sensing system (e.g., dualheat flux sensor 214 and absolute temperature sensor 216). Theelectronic device 200 can be included in, for example,mobile telephone 136,digital media player 140,personal computer 144,tablet computing device 148,wearable device 150, or any mobile or non-mobile computing device. - In some examples, the
electronic device 200 can include an integrated display (e.g., touch screen) 212 to display images and to detect touch and/or proximity (e.g., hover) events from an object (e.g., active or passive stylus or finger) at or proximate to the surface of thedisplay 212. - In some examples, the
electronic device 200 can include a power source 208 (e.g., energy storage device such as a battery),processor 204,program storage device 210 and/ormemory 206,wireless communication circuitry 202, and a temperature sensing system (e.g., a dualheat flux sensor 214 and absolute temperature sensor 216). Theprocessor 204 can control some or all of the operations of theelectronic device 200. Theprocessor 204 can communicate, either directly or indirectly, with some or all of the other components of theelectronic device 200. For example, a system bus or other communication mechanism can provide communication between thepower source 208, theprocessor 204, thedisplay 212, theprogram storage device 210, thememory 206, thewireless communication circuitry 202, and the temperature sensing system (e.g., a dualheat flux sensor 214 and absolute temperature sensor 216). - The
processor 204 can be implemented as any electronic device capable of processing, receiving, or transmitting data or instructions, whether such data or instructions is in the form of software or firmware or otherwise encoded. For example, theprocessor 204 can include a microprocessor, a central processing unit (CPU), an application-specific integrated circuit (ASIC), a digital signal processor (DSP), a controller, or a combination of such devices. As described herein, the term “processor” or “processing circuitry” is meant to encompass a single processor or processing unit, multiple processors, multiple processing units, or other suitably configured computing element or elements. In some examples,processor 204 can provide part or all of the processing systems or processors described with reference to any ofFIGS. 3-8 . - The
processor 204 can receive touch input to thedisplay 212 or other input devices and perform actions based on the outputs. For example, theprocessor 204 can be connected to the program storage 210 (and/or memory 206) and a display controller/driver to generate images on the display screen. The display screen includes, but is not limited to, Liquid Crystal Display (LCD) displays, Light-Emitting Diode (LED) displays, including Organic LED (OLED), Active-Matrix Organic LED (AMOLED), Passive-Matrix Organic LED (PMOLED) displays, a projector, a holographic projector, a retinal projector, or other suitable display. In some examples, the display driver can provide voltages on select (e.g., gate) lines to each pixel transistor and can provide data signals along data lines to these same transistors to control the pixel display image for thedisplay 212. - The
processor 204 can cause a display image on thedisplay 212, such as a display image of a user interface (UI) or display a notification indicating ambient temperature and/or internal body temperature, and can use touch processor and/or touch controller to detect a touch on or near thedisplay 212, such as a touch input to the displayed UI when theelectronic device 200 includes a touch screen. The touch input can be used by computer programs stored inprogram storage 210 to perform actions that can include, but are not limited to, moving an object such as a cursor or pointer, scrolling or panning, adjusting control settings, opening a file or document, viewing a menu, making a selection, executing instructions, operating a peripheral device connected to the host device, answering a telephone call, placing a telephone call, terminating a telephone call, changing the volume or audio settings, storing information related to telephone communications such as addresses, frequently dialed numbers, received calls, missed calls, logging onto a computer or a computer network, permitting authorized individuals access to restricted areas of the computer or computer network, loading a user profile associated with a user's preferred arrangement of the computer desktop, permitting access to web content, launching a particular program, encrypting or decoding a message, and/or the like. Theprocessor 204 can also perform additional functions that may not be related to touch processing or temperature sensing. - Note that one or more of the functions described in this disclosure can be performed by firmware stored in
memory 206 and/or stored inprogram storage 210 and executed by theprocessor 204 or other processing circuitry of theelectronic device 200. The firmware can also be stored and/or transported within any non-transitory computer-readable storage medium for use by or in connection with an instruction execution system, apparatus, or device, such as a computer-based system, processor-containing system, or other system that can fetch the instructions from the instruction execution system, apparatus, or device and execute the instructions. In the context of this document, a “non-transitory computer-readable storage medium” can be any medium (excluding signals) that can contain or store the program for use by or in connection with the instruction execution system, apparatus, or device. In some examples, theprogram storage 210 and/ormemory 206 can be a non-transitory computer readable storage medium. The non-transitory computer readable storage medium (or multiple thereof) can have stored therein instructions, which when executed by theprocessor 204 or other processing circuitry, can cause the device including the computingelectronic device 200 to perform one or more functions and methods of one or more examples of this disclosure. The computer-readable storage medium can include, but is not limited to, an electronic, magnetic, optical, electromagnetic, infrared, or semiconductor system, apparatus or device, a portable computer diskette (magnetic), a random access memory (RAM) (magnetic), a read-only memory (ROM) (magnetic), an erasable programmable read-only memory (EPROM) (magnetic), a portable optical disc such a CD, CD-R, CD-RW, DVD, DVD-R, or DVD-RW, or flash memory such as compact flash cards, secured digital cards, USB memory devices, memory sticks, and the like. - The firmware can also be propagated within any transport medium for use by or in connection with an instruction execution system, apparatus, or device, such as a computer-based system, processor-containing system, or other system that can fetch the instructions from the instruction execution system, apparatus, or device and execute the instructions. In the context of this document, a “transport medium” can be any medium that can communicate, propagate or transport the program for use by or in connection with the instruction execution system, apparatus, or device. The transport medium can include, but is not limited to, an electronic, magnetic, optical, electromagnetic or infrared wired or wireless propagation medium.
- The
power source 208 can be implemented with any device capable of providing energy to theelectronic device 200. For example, thepower source 208 can include one or more batteries or rechargeable batteries. Additionally or alternatively, thepower source 208 can include a power connector or power cord that connects theelectronic device 200 to another power source, such as a wall outlet. - The
memory 206 can store electronic data that can be used byelectronic device 200. For example,memory 206 can store electrical data or content such as, for example, audio and video files, documents and applications, device settings and user preferences, timing signals, control signals, and data structures or databases. Thememory 206 can include any type of memory. By way of example only, thememory 206 can include random access memory, read-only memory, Flash memory, removable memory, other types of storage elements, or combinations of such memory types. - The dual
heat flux sensor 214 can measure voltage associated with a thermopile that is directly proportional to a temperature gradient and/or heat flux. Theabsolute temperature sensor 216 can measure temperature at given locations (e.g., top surface of outer thermopile, bottom surface of outer thermopile, top surface of inner thermopile, bottom surface of inner thermopile). In addition to the dualheat flux sensor 214 andabsolute temperature sensor 216, theelectronic device 200 can include sensing device(s) that can include sensors circuitry configured to sense one or more types of parameters, such as but not limited to, vibration; light; touch; force; heat; movement; relative motion; biometric data (e.g., biological parameters) of a user; air quality; proximity; position; connectedness; and so on. In some examples, the sensing device(s) can include an image sensor such as an outward facing camera, a radiofrequency sensor (and/or transmitter), an infrared sensor (and/or transmitter), a magnetic sensor (and/or generator) (e.g., a magnetometer), an ultrasonic sensor (and/or transmitter), and/or an inertial measurement unit. In some examples, the sensing device(s) can further include other sensor(s) including a force sensor, a heat sensor, a position sensor, a light or optical sensor, an accelerometer, a pressure transducer, a gyroscope, an acoustic sensor, a health monitoring sensor, and/or an air quality sensor, among other possibilities. Additionally, the one or more sensors of the sensing device(s) can utilize any suitable sensing technology, including, but not limited to, interferometric, magnetic, capacitive, ultrasonic, resistive, optical, acoustic, piezoelectric, or thermal technologies. -
Wireless communication circuitry 202 can transmit or receive data from another electronic device. Althoughwireless communication circuitry 202 is illustrated and described, it is understood that other wired communication interfaces may be used. In some examples, the wireless and/or wired communications interfaces can include, but are not limited to, cellular, Bluetooth, and/or Wi-Fi communications interfaces. Although not shown, theelectronic device 200 can also include other input/output mechanisms including one or more touch sensing input surfaces, a crown, one or more physical buttons, one or more microphones or speakers, one or more ports such as a microphone port, and/or a keyboard. - It should be apparent that the architecture shown in
FIG. 2 is only one example architecture of theelectronic device 200 and that the device could have more or fewer components than shown, or a different configuration of components. The various components shown inFIG. 2 can be implemented in hardware, software, firmware, or any combination thereof, including one or more signal processing and/or application specific integrated circuits. - In some examples, an electronic device (e.g., wearable device) can simultaneously determine thermal resistance of skin and internal body temperature. As such,
FIG. 3 illustrateswearable device 300 configured to measure thermal resistance of skin (e.g., Rwrist) 312 andinternal body temperature 306. Thewearable device 300 can correspond to adevice 150 ofFIG. 1E (or more generally can correspond to any of the electronic devices illustrated byFIGS. 1A-1E ).Wearable device 300 can include ahousing 301 secured to a user via a strap or any other suitable fastener (e.g., corresponding to strap 154). In some examples, thewearable device 300 can be secured to a user (e.g., exposed skin on the user's body). Thewearable device 300 can correspond to a watch, a fitness tracker, or any other device (e.g., optionally used to measure physiological signals associated with the user). Thewearable device 300 can attach to the user around the wrist (e.g., corresponding to layer of skin at a user's wrist 310), head, over the eyes, or on any exposed surface of the body that is suitable for measuring physiological signals (e.g., internal body temperature 306) associated with the user. - The
wearable device 300 can include afront face 303, thehousing 301 and aback face 305. Thefront face 303 is sometimes referred to herein as the “front crystal” of thewearable device 300, and theback face 305 is sometimes referred to herein as the “back crystal” of thewearable device 300. However, it should be understood that thefront face 303 and back face 305 generally refer to a substrate such as glass, plastic, resin, gel, or crystal. For example, thefront face 303 and the back face 305 (also referred to as a rear face) can protect internal components of thewearable device 300, but also allow for optical transmission from a display screen (e.g., touch screen) and/or optical sensors. In some examples, the temperature sensing system within thewearable device 300 can be used to measure temperatures associated with a touch screen located at thefront face 303. In such examples, the temperature sensing system can be configured to measure the temperature at a location or region inside wearable device 300 (e.g., optionally closer to the front face 303). Alternatively, or additionally, the temperature sensing system can be used to measure the temperature outside ofwearable device 300, such as the temperature of air contacting thefront face 303, or the temperature of other objects at least partially in contact with, or overlapping thefront face 303, as described inFIG. 4 . - In some examples, the temperature sensing system within the
wearable device 300 can be used to measure temperatures associated with an optical system located at theback face 305. In such examples, the temperature sensing system can be configured to measure the temperature at a location or region inside the wearable device 300 (e.g., optionally closer to the back face 305). Alternatively, or additionally, the temperature sensing system can be used to measure the temperature outside of thewearable device 300, such as the temperature of air contacting back face as described inFIG. 4 , or the temperature of other objects at least partially in contact with, or overlapping, back face (e.g., skin temperature at the wrist). Finally, the temperature sensing system can be used to measure the temperature at any location withinwearable device 300, as well as the temperature of objects outside wearable device 300 (e.g., the air surrounding wearable device as described inFIG. 4 ), or objects at least partially in contact with thefront face 303, theback face 305, or the housing 301). - In some examples, a sensing glass, a printed circuit board (PCB), and the like can be disposed inside the
housing 301. For example, the sensing glass or the printed circuit board (PCB) can be located inside thewearable device 300, at the front face 303 (sometimes referred to as a “front crystal”). The printed circuit board (PCB) can include optical sensors configured to emit light and detect light through thefront face 303. In some examples, the sensing glass or the printed circuit board (PCB) can be used to implement a touch sensor panel, display or touch screen (e.g., touch screen 152) disposed below thefront face 303. In some examples, the sensing glass or the printed circuit board (PCB) can include a processor (e.g., corresponding to processor 204), program storage (e.g., corresponding to program storage 210), optionally a touch and display controller, and/or temperature sensing devices (e.g., thermopiles of the dualheat flux sensor 214, absolute temperature sensor 216). In some examples, the sensing glass or the printed circuit board (PCB) can additionally or alternatively include one or more discrete absolute temperature sensors. - In some examples, the sensing glass or the printed circuit board (PCB) can be located inside the
wearable device 300, at the back face 305 (sometimes referred to as a “back crystal”). The printed circuit board (PCB) can include optical sensors configured to emit light and detect light through the back face. It should be understood that the number of sensing glass layers or printed circuit boards (PCBs), placement of sensing glass or the printed circuit boards PCBs, and distribution of components within thewearable device 300 is non-limiting. - In some cases, measurements of internal body temperature (Tinner) 306 can be susceptible to error from variances in thermal resistance of skin (e.g., person-to-person variations in skin properties such as fat tissue corresponding to Rwrist 312). Accordingly, the sensing glass or the printed circuit board of the
wearable device 300 can include thermopile(s) (e.g., inner and outer thermopiles). Each of the thermopile(s) can generate a temperature differential or gradient measurement between a bottom surface of the sensing glass or printed circuit board (PCB) and a top surface of the sensing glass or printed circuit board (e.g., when through-hole vias are used to form the thermopile(s)). For example, the inner thermopile and the outer thermopile can have different heat paths (e.g., temperature gradients). Temperature gradient measurements of the thermopiles (e.g., inner thermopile, outer thermopile) can be used for determining heat flux through a user wrist's (Qwrist) 308. - Given the heat flux associated with the inner thermopile, heat flux associated with the outer thermopile, temperature of the front crystal (Tfc) 314, temperature of the back crystal (Tbc) 304, and resistance of the
wearable device 300, such as a watch (e.g., Rwatch) 302, the temperature sensing system can simultaneously measure the thermal resistance of skin, such as resistance associated with fat tissue of user's wrist (e.g., Rwrist) 312, and the internal body temperature (Tinner) 306 of a user. In some examples, using the heat flux associated with the inner thermopile, heat flux associated with the outer thermopile, temperature of the front crystal, (Tfc) 314, temperature of the back crystal (Tbc) 304, and resistance of thewearable device 300, such as a watch (e.g., Rwatch) 302 as inputs, processing circuitry of the temperature sensing system and/or thewearable device 300 can simultaneously measure the thermal resistance of skin (e.g., Rwrist) 312 and the internal body temperature (Tinner) 306 of a user. Rather than assuming thermal resistance of skin (e.g., Rwrist) 312 (e.g., such as using a lookup table of varying Rwrist values) and without taking into account person-to-person variations in skin properties to determine internal body temperature (Tinner) 306, a temperature sensing system that includes at least inner and outer thermopiles can be used to accurately determine the thermal resistance of skin (e.g., Rwrist) 312 and internal body temperature (Tinner) 306 of the user. In some examples, thewearable device 300 and/or the temperature sensing system can include any suitable number and arrangement of absolute temperature sensors. An absolute temperature sensor placed at the front crystal of the wearable device 300 (e.g., watch) can measure temperature at the front crystal (Tfc) 314, and an absolute temperature sensor temperature placed at the back crystal of the wearable device 300 (e.g., watch) can measure temperature at the back crystal (Tbc) 304. - In some examples, an electronic device (e.g., wearable device) can also simultaneously determine thermal resistance of air (e.g., convection coefficient) and ambient temperature. As such,
FIG. 4 illustrateswearable device 400 configured to measure thermal resistance of air (h) 406 ambient temperature (T∞) 408. Thewearable device 400 corresponds to thewearable device 300 described inFIG. 3 , thereby includes ahousing 401, afront face 403, and aback face 405. - Measurements of ambient temperature (T∞) 408 can be susceptible to error from variances in thermal resistance of air (e.g., wind speed and humidity corresponding to h 406). Accordingly, sensing glass or the printed circuit board (PCB) of the
wearable device 400 can include thermopile(s) (e.g., inner and outer thermopiles). Each of the thermopile(s) can generate a temperature differential or gradient measurement between a bottom surface of the sensing glass or printed circuit board (PCB) and a top surface of the sensing glass or printed circuit board (e.g., when through-hole vias are used to form the thermopile(s)). For example, the inner thermopile and the outer thermopile can have different heat paths (e.g., temperature gradients). Temperature gradient measurements of the thermopiles (e.g., inner thermopile, outer thermopile) can be used for determining heat flux associated with the inner thermopile and the outer thermopile. - Given heat flux associated with the inner thermopile, heat flux associated with the outer thermopile, temperature of the front crystal (Tfc) 414, temperature of the back crystal (Tbc) 404, and resistance of the
wearable device 400, such as a watch (e.g., Rwatch) 402, the temperature sensing system can simultaneously measure the thermal resistance of air (h) 406 and the ambient temperature (T∞) 408. In some examples, using the heat flux associated with the inner thermopile, heat flux associated with the outer thermopile, temperature of the front crystal (Tfc) 414, temperature of the back crystal (Tbc) 404, and resistance of thewearable device 400, such as a watch (e.g., Rwatch) 402 as inputs, processing circuitry of the temperature sensing system and/or thewearable device 400 can simultaneously measure the thermal resistance of air (h) 406 and the ambient temperature (T∞) 408. Rather than assuming thermal resistance of air (h) 406 to determine the ambient temperature (T∞) 408, a temperature sensing system that includes at least inner and outer thermopiles can be used to accurately determine the thermal resistance of air (h) 406 and the ambient temperature (T∞) 408. In some examples, thewearable device 400 and/or the temperature sensing system can include any suitable number and arrangement of absolute temperature sensors. An absolute temperature sensor placed at the front crystal of the wearable device 400 (e.g., watch) can measure temperature at the front crystal (Tfc) 414, and an absolute temperature sensor temperature placed at the back crystal of the wearable device 300 (e.g., watch) can measure temperature at the back crystal (Tbc) 404. -
FIG. 5 illustrates a cross-section of an example temperature sensing system according to examples of the disclosure. A temperature sensing system (e.g., dual heat flux sensor) 500 can include at least a block (e.g., housing) 508 and sensing glass 504 (also referred to as a first glass substrate) embedded with aninner thermopile 510 and anouter thermopile 512. In some examples, thesensing glass 504 can be disposed within or coupled to theblock 508. In some examples, the temperature sensing system can also include passivation layer 502 (also referred to as a passivation glass or a second glass substrate, when the passivation layer material is glass), acavity 506 disposed within theblock 508, thermal insulation layer(s) 520, absolute temperature sensor(s), and/or additional thermopiles. It should be noted that the number and distribution of components within thetemperature sensing system 500 is non-limiting. - The
sensing glass 504 can include theinner thermopile 510 and theouter thermopile 512. As described above, theinner thermopile 510 and theouter thermopile 512 separately measure heat flux, which is used to determine internal body temperature and/or ambient temperature. In some examples, a temperature gradient associated with the inner thermopile 510 (T3−T1) can be different than the temperature gradient associated with the outer thermopile 512 (T4−T2). T3−T1 represents a temperature gradient between a top surface of theinner thermopile 510 and a bottom surface of theinner thermopile 510. T4−T2 represents a temperature gradient between a top surface of theouter thermopile 512 and a bottom surface of theouter thermopile 512. Although not illustrated, thetemperature sensing system 500 can include any number of absolute temperature sensors. For example, thetemperature sensing system 500 can include a first absolute temperature located near T3 to measure temperature at a top surface of theinner thermopile 510, a second absolute temperature located near T1 to measure temperature at a bottom surface of theinner thermopile 510, a third absolute temperature located near T4 to measure temperature at a top surface of theouter thermopile 512, and a fourth absolute temperature located near T2 to measure temperature at a bottom surface of theouter thermopile 512. In some examples, theinner thermopile 510 has a diameter between 0.01-10 millimeters. In some examples, theinner thermopile 510 has a diameter of 0.01, 0.003, 0.055, 0.1, 0.5, 1, or 1.5 millimeters. In some examples, theouter thermopile 512 has a diameter between 0.05-15 millimeters. In some examples, theouter thermopile 512 has a diameter of 0.05, 0.5, 1 3, 5, 8 or 10 millimeters. In some examples and as illustrated inFIG. 5 , theinner thermopile 510 and theouter thermopile 512 can include through hole thermopiles, which traverse thesensing glass 504 from top to bottom. In some examples, theinner thermopile 510 and theouter thermopile 512 can include blind thermopiles, buried thermopiles, and/or micro-thermopiles. In some examples, theheight 514 of theinner thermopile 510 and theheight 516 of theouter thermopile 512 can be between 0.1-5 millimeters. In some examples,height 514 andheight 516 can be 0.1, 0.5, 1. 5, 2, 3, or 5 millimeters. It should be appreciated thatheight 514 of theinner thermopile 510 andheight 516 of theouter thermopile 512 are shown to be equal. By having no step up or height difference between theinner thermopile 510 and theouter thermopile 512, the temperature sensing system can be thinner, more compact, less expensive to manufacture, and easier to integrate into compact housings (e.g., watch). It is understood that, in some examples, there can be a small height differential within the manufacturing tolerance. - In some examples,
passivation layer 502 can be disposed above the sensing glass 504 (e.g., near the front crystal of a wearable device). Thepassivation layer 502 can prevent electrical shorting between the wearable device (e.g., including the temperature sensing system 500) and the environment. In some examples,passivation layer 502 can also be disposed near the back crystal of the wearable device. In some examples, thepassivation layer 502 includes epoxy, glass, a polymer material, a ceramic material (e.g., silicon nitride), a composite material, and so forth. In some examples, thepassivation layer 502 has a height between 100 nanometers and 1 millimeter. In some examples, thepassivation layer 502 has a height of 100 nanometers, 500 nanometers, 1000 nanometers, 10 microns, 100 microns, or 1000 microns. In some examples, lateral (e.g., vertical) edge(s) of the temperature sensing system include thermal insulation layer(s) 520. In some examples, the thermal insulation layer(s) 520 can be external to theblock 508. In some examples, the thermal insulation layer(s) 520 are disposed a threshold distance (0.5, 1, 2, 3, 5, etc. millimeters) from theouter thermopile 512. The thermal insulation layer(s) 520 can include epoxy, glass, plastic, and so forth to prevent electrical shorting. The thermal insulation layers(s) 520 can have a diameter between 100 nanometers and 1 millimeter. In some examples, the thermal insulation layers(s) 520 can have a diameter of 100 nanometers, 500 nanometers, 1000 nanometers, 10 microns, 100 microns, or 1000 microns. - In some examples, the
cavity 506 can be disposed below thesensing glass 504 and within theblock 508. Thecavity 506 can include an air cavity or a vacuum cavity. In some examples, aglass layer 506 that is different from thesensing glass 504 and/or thepassivation layer 502 can be disposed below thesensing glass 504 and within theblock 508. The cavity orglass layer 506 can have adiameter 522 between 0.5 to 6 millimeters. In some examples, the cavity orglass layer 506 can have a diameter of 0.5, 1, 1,5, 2, 3, 4, 5, or 6 millimeters. The cavity orglass layer 506 can have a height between 0.1 to 3 millimeters. In some examples, the cavity orglass layer 506 can have aheight 524 of 0.1, 0.5, 1, 1.5, 2, 2.5, or 3 millimeters. In some examples, adiameter 528 of thetemperature sensing system 500 is at least 1.5 times greater than the diameter of theouter thermopile 512. In some examples, thediameter 528 of thetemperature sensing system 500 can be between 6 and 15 millimeters. In some examples, thediameter 528 of thetemperature sensing system 500 can be between 9 and 12 millimeters. In some examples, aheight 526 of thetemperature sensing system 500 can be between 3.5 and 5 millimeters. In some examples, a 526 of thetemperature sensing system 500 is less than 4 millimeters. It is understood that the diameters and heights or ranges of diameters and heights can be different than those above, depending on the size requirements of the temperature sensing system. - In some examples, the
temperature sensing system 500 can include any number and arrangement of absolute temperature sensors and thermopiles. In some examples, in addition to a temperature gradient (e.g., heat flux, T3−T1) associated with theinner thermopile 510 and a temperature gradient (e.g., heat flux, T4−T2) associated with theouter thermopile 512, a lateral temperature difference 518 (T4−T3) or (T2−T1) between theinner thermopile 510 and theouter thermopile 512 as well as at least one absolute temperature (e.g., T1, T2, T3, or T4) are used to determine thermal resistance of skin and internal body temperature. In some examples, the temperature gradient (e.g., heat flux) associated with theinner thermopile 510, the temperature gradient (e.g., heat flux) associated with theouter thermopile 512, and thelateral temperature difference 518 between theinner thermopile 510 and theouter thermopile 512 can also be used to determine thermal resistance of air and ambient temperature. In some examples, thelateral temperature difference 518 can be measured using an additional surface thermopile disposed between the inner thermopile and the outer thermopile (e.g., along a surface of sensing glass 504). In some examples, a first absolute temperature sensor can be disposed at a bottom surface of theinner thermopile 510 to measure T1 and a second absolute temperature sensor can be disposed at a bottom surface of theouter thermopile 512 to measure T2. Based on a temperature associated with the bottom surface of theinner thermopile 510, and a temperature associated with the bottom surface of theouter thermopile 512, lateral temperature difference 518 (e.g., T1−T2) can be determined. In some examples, a third absolute temperature sensor can be disposed at a top surface of theinner thermopile 510 to measure T3 and a fourth absolute temperature sensor can be disposed at a bottom surface of theouter thermopile 512 to measure T4. Based on a temperature associated with the top surface of theinner thermopile 510, and a temperature associated with the top surface of theouter thermopile 512, lateral temperature difference 518 (e.g., T3−T4) can be determined. In some examples, the temperature gradient associated with theinner thermopile 510, the temperature gradient associated with theouter thermopile 512, thelateral temperature difference 518, and at least one absolute temperature from T1, T2, T3, or T4 can be used to determine internal body temperature and/or ambient temperature. In some examples, rather than using the temperature gradients associated with theinner thermopile 510 and theouter thermopile 512, at least four absolute temperatures (e.g., T1, T2, T3, and T4) can be used to determine internal body temperature and/or ambient temperature. In some examples, as illustrated inFIG. 5 , T1 can represent a location of a first absolute temperature sensor, T2 can represent a location a second absolute temperature sensor, T3 can represent a location of a third absolute temperature sensor, and T4 can represent a location of a fourth absolute temperature sensor can form a concentric ring structure. In some examples, the first absolute temperature sensor, the second absolute temperature sensor, the third absolute temperature sensor, and the fourth absolute temperature sensor can include vapor deposited, nickel-chromium resistance temperature detectors (NiCr RTDs). In some examples, the temperature gradient associated with theinner thermopile 510, the temperature gradient associated with theouter thermopile 512, and least two absolute temperatures (e.g., T1 and T2) can be used to determine internal body temperature and/or ambient temperature. In some examples, any suitable combination of the temperature gradient associated with theinner thermopile 510, the temperature gradient associated with theouter thermopile 512, thelateral temperature difference 518, and one or more absolute temperatures can be used to determine internal body temperature and/or ambient temperature. -
FIG. 6 illustrates a cross-sectional side view of an example temperature sensing system according to examples of the disclosure. Thetemperature sensing system 600 can include a layer ofsensing glass 604 or a printed circuit board (PCB) embedded withinner thermopile 610 andouter thermopile 612. Temperature gradients associated withinner thermopile 610 andouter thermopile 612 can be used to determine thermal resistance of skin (Rwrist) and internal body temperature (Tinner). Additionally or alternatively, temperature gradients associated withinner thermopile 610 andouter thermopile 612 can be used to determine thermal resistance of air (h) and ambient temperature (T∞). - In some examples, to determine internal body temperature and/or ambient temperature, system equations [1] and/or [2] can be used.
-
- In some examples, equation [1] can be used to determine the thermal resistance of skin and/or internal body temperature. To determine internal body temperature, equation [1] can be used to determine heat conduction associated with the
inner thermopile 610, where Rpath can represent a first heat path from subsurface tissue of a user's body (e.g., resistance of fat tissue associated with the user's wrist) to the user's wrist (e.g., resistance of skin at the user's wrist). δT can represent the change in temperature (e.g., temperature gradient) associated with theinner thermopile 610. Further, equation [1] can be used to determine heat conduction associated with theouter thermopile 612, where Rpath can represent a second heat path from the user's wrist (e.g., resistance of skin at a user's wrist) to a user's watch (e.g., resistance of the watch). δT can represent the change in temperature (e.g., temperature gradient) of theouter thermopile 612. - In some examples, equation [1] and/or equation [2] can be used to determine thermal resistance of air (h) and/or ambient temperature. To determine ambient temperature, equation [1] can be used to determine heat conduction associated with the
inner thermopile 610, where Rpath can represent a third heat path from the user's wrist (e.g., resistance of skin at the user's wrist) to the user's watch (e.g., resistance of the watch). Further, equation [1] can be used to determine heat conduction associated with theouter thermopile 612, where Rpath can represent a fourth heat path from the user's watch (e.g., resistance of the watch) to the ambient environment (e.g., resistance associated with wind speed and humidity). In some examples, only equation [1] using the third and fourth heath paths described above can be used to determine ambient temperature. In some examples, both equations [1] and [2] can be used to determine ambient temperature. In some examples, only equation [2] can be used to determine the ambient temperature. To determine the ambient temperature, equation [2] can be used to determine heat convection associated with theinner thermopile 610, where Asurface can represent surface area of theinner thermopile 610 exposed to air. Further, equation [2] can be used to determine heat convection associated with theouter thermopile 612, where Asurface can represent surface area of theouter thermopile 612 exposed to air. - In some examples, to determine thermal resistance of skin (Rwrist) and internal body temperature equations (Tinner) equations [3] and [4] can be used. Equations [3] and [4] represent equation [1] using the temperature gradient and thermal resistance for each path illustrated in
FIGS. 5-6 (e.g., first heat path associated with the inner thermopile and second heat path associated with the outer thermopile. -
- Equation [3] represents heat flux (e.g., Q1) associated with the
inner thermopile 610. T3−T1 represents a temperature gradient between a top surface of theinner thermopile 610 and a bottom surface of theinner thermopile 610. R1-3 represents thermal resistance between the top surface of theinner thermopile 610 and the bottom surface of theinner thermopile 610. Equation [4] represents heat flux (e.g., Q2) associated with theouter thermopile 612. T4−T2 represents a temperature gradient between a top surface of theouter thermopile 612 and a bottom surface of theouter thermopile 612. R2-4 represents thermal resistance between the top surface of theouter thermopile 612 and the bottom surface of theouter thermopile 612. - In some examples, internal body temperature (Tinner) can be determined using the following equation:
-
- In some examples, thermal resistance of skin (Rwrist) and internal body temperature (Tinner) can be determined based at least on the temperature gradient (T3−T1) associated with the
inner thermopile 610, the temperature gradient (T4−T2) associated with theouter thermopile 612, a lateral temperature difference between theinner thermopile 610 and theouter thermopile 612, and an absolute temperature. - In some examples, to determine thermal resistance of air (h) and ambient temperature (T∞), system equations [6] and [7] can be used. Equations [6] and [7] represent equations [1]and [2] using the temperature gradient and thermal resistance for each path illustrated in
FIGS. 5-6 . -
- Equation [6] represents heat flux (e.g., Q1) associated with the
inner thermopile 610. The heat flux (e.g., Q1) in equation 6 is equal to -
- which is representative of the third heat path associated with the
inner thermopile 610 based on equation [1], and equal to T3−T∞ based on equation [2]. T1−T3 represents a temperature gradient between a top surface of theinner thermopile 610 and a bottom surface of theinner thermopile 610. R1-3 represents thermal resistance between the top surface of theinner thermopile 610 and the bottom surface of theinner thermopile 610. A3 represents the surface area of a heat path associated with theinner thermopile 610 exposed to the ambient environment. Equation [7] represents heat flux (e.g., Q2) associated with theouter thermopile 612. The heat flux (e.g., Q2) in equation 7 is equal to -
- which is representative of the fourth heat path associated with the
outer thermopile 612 based on equation [1], and equal to T4−T∞ based on equation [2]. T2−T4 represents a temperature gradient between a top surface of theouter thermopile 612 and a bottom surface of theouter thermopile 612. R2-4 represents thermal resistance between the top surface of theouter thermopile 612 and the bottom surface of theouter thermopile 612. A4 represents the surface area of a heat path associated with theouter thermopile 610 exposed to the ambient environment. - In some examples, ambient temperature (T∞) can be determined using the following equation:
-
- As mentioned above, thermal resistance of air (h) and ambient temperature (T∞) can be determined based at least on the temperature gradient (T1−T3) associated with the
inner thermopile 610, the temperature gradient (T2−T4) associated with theouter thermopile 612, the lateral temperature difference between theinner thermopile 610 and theouter thermopile 612, and an absolute temperature. - As discussed above and in some examples, inner and outer thermopiles are uniform in height and configured to form concentric geometries. Accordingly,
FIG. 7A illustrates an exampletemperature sensing system 700 includinginner thermopile 702 andouter thermopile 704 forming concentric shapes (e.g., concentric cylinders, concentric polygonal shapes, concentric geometric shapes, concentric non-geometric shapes) according to examples of the disclosure. By having little to no step up or height difference between theinner thermopile 702 and theouter thermopile 704, the temperature sensing system can be thinner, more compact, less expensive to manufacture, and easier to integrate into compact housings (e.g., watch, wearables, portables, etc.). In some examples, theinner thermopile 702 and theouter thermopile 704 can be separated by a layer of sensing glass or a layer of a printed circuit board (PCB).FIG. 7B illustrates a top view of an exampletemperature sensing system 750 that includes anadditional thermopile 752 disposed between an inner thermopile (e.g., corresponding to inner thermopile 702) and an outer thermopile (e.g., corresponding to outer thermopile 704). As illustrated, theadditional thermopile 752 can measure a lateral temperature gradient (T3−T4) between a top surface of the inner thermopile and a top surface of the outer thermopile. In some examples, theadditional thermopile 752 can measure a lateral temperature gradient (T1−T2) between a bottom surface of the inner thermopile and a bottom surface of the outer thermopile. - In some examples, each thermopile can be formed from a series of thermocouples. In some examples, each thermocouple includes at least two dissimilar conductive materials (e.g., copper and constantan). As such,
FIG. 8A illustrates a schematic illustration of an example thermopile 810 (e.g., inner thermopile, outer thermopile) formed from a series ofthermocouples 808 according to examples of the disclosure. For example, an inner thermopile (e.g., corresponding to inner thermopile 702) can include a first set of dissimilar conductive materials (e.g., metal fillings) different from a second set of dissimilar conductive materials of the outer thermopile (e.g., corresponding to outer thermopile 704). In some examples, the inner thermopile can include a first set of dissimilar conductive materials (e.g., metal fillings) that are similar to second set of dissimilar conductive materials of the outer thermopile. In some examples, each of the first and second set of dissimilar conductive materials can include any number of dissimilar metals or alloys (e.g., 2, 3, 4, or 5 different metals). Non-limiting examples of the first set of dissimilar conductive materials includes copper and constantan; chromel and constantan; chromium and constantan; nickel, copper, and chromium; and copper and chromium. Non-limiting examples of the second set of dissimilar conductive materials includes copper and constantan; chromel and constantan; chromium and constantan; nickel, copper, and chromium; and copper and chromium. - To manufacture the embedded inner thermopile and the outer thermopile within sensing glass, via holes can be formed through a layer of the sensing glass, and filled with respective vias (e.g., respective conductive materials). In some examples, the inner thermopile and the outer thermopile can be embedded within a printed circuit board (PCB). As such, various printed circuit board (PCB) processing methods, using with various materials (e.g., high volume production processes) can be used to create the vias. Deposition methods for forming the different layers include printing, dispensing material into holes/vias, and vacuum printing.
- For example, a first via 800 can be filled with copper, copper particles suspended in epoxy, or copper-coated particles suspended in epoxy (e.g., according to a “via fill” manufacturing process). Additionally or alternatively, the first via 800 can be filled with aluminum, gold, carbon ink, or any suitable metal or alloy. Similarly, a second via 802 can be filled with such as constantan, constantan particles suspended in epoxy, or constantan-coated particles suspended in epoxy. Additionally or alternatively, the second via 802 can be filled with aluminum, gold, carbon ink, or any suitable metal or alloy. In some examples, if the inner thermopile and the
outer thermopile 704 are embedded within the printed circuit board (PCB), then the two vias can be then connected via aconductive trace 804. In some examples, theconductive trace 804 can include copper, aluminum, gold, carbon ink, or any suitable metal or alloy. In some examples, if the inner thermopile and the outer thermopile are embedded within the printed circuit board (PCB), the twovias copper connector 804. Connecting the first andsecond vias copper connecter 804 forms a thermocouple, when the metal filled in the first via 800 has a different Seebeck coefficient than the metal filled in the second via 802. Since the first andsecond vias thermopile 810 formed from the series combination of such vias measures heat flux, or the temperature differential/gradient, across the height of the sensing glass or the printed circuit board (PCB). Each pair of connected vias, such as the first andsecond vias thermocouple 808, and connecting such pairs of connected vias forms athermopile 810 embedded within the sensing glass or the printed circuit board (PCB). In some examples, eachthermocouple 808 can be two-dimensional, and a series ofthermocouples 808 can form a multidimensional (e.g., three-dimensional)thermopile 810. Thethermopile 810 can output avoltage measurement 806 that is directly proportional to a temperature gradient and/or heat flux, which can help determine internal body temperature and/or ambient temperature. -
FIG. 8B illustrates a top view of exampleinner thermopile 850 andouter thermopile 852 according to examples of the disclosure. In some examples, theinner thermopile 850 can include a cluster of thermocouples (e.g., forming a “solid” cylindrical shape, a rectangular shape, a geometric shape, or a non-geometric shape). In some examples, the cluster of thermocouples of theinner thermopile 850 can be concentric or non-concentric. In some examples, theinner thermopile 850 can include any number of thermocouple rows and any number of thermocouple columns. In some examples, theouter thermopile 852 can include a cluster of thermocouples (e.g., forming a “hollow” cylindrical shape, a rectangular shape, a geometric shape, or a non-geometric shape) can include any number of thermocouple rows, such as 6 rows of thermocouples as illustrated inFIG. 8B , and any number of thermocouple columns. In some examples, the cluster of thermocouples of theouter thermopile 852 can be concentric in relation to the cluster of thermocouples of the inner thermopiles. In some examples, the cluster of thermocouples of theouter thermopile 852 can be non-concentric. - In some examples, the temperature sensing system (e.g., dual heat flux sensor) described in
FIGS. 2-7 is disposed in the wearable device (e.g., watch) such that the temperature sensing system measures a vertical gradient (e.g., parallel to a line from the front face to the rear face). Alternatively, in some examples, the temperature sensing system is disposed in the wearable device such that the temperature sensing system measures a lateral gradient (e.g., perpendicular to a line from the front face to the rear face). In some examples, more than one temperature sensing systems can be integrated into a wearable device, such as a first temperature sensing system that measures a vertical gradient and a second temperature sensing system that measures a lateral gradient. The use of one or more temperature sensing systems measuring one or more lateral gradients can allows the wearable device to account for variances in thermal resistance of skin (e.g.,skin 902 inFIGS. 9A-9B ) and/or air (e.g., variances in thermal resistance due to variance in amount of fat tissue, wind speed, humidity) when determining ambient temperature and/or internal body temperature. In some examples, a wearable device that includes at least two temperature sensing systems improves accuracy of temperature and/or internal body temperature measurements. In some examples, a wearable device that includes a first temperature sensing system disposed at or near (within a threshold distance of) a center of the wearable device (optionally near a front face or rear face) and a second temperature sensing system disposed at or near (within a threshold distance of) a side of the wearable device to measure a lateral gradient can improve accuracy of temperature and/or internal body temperature measurements. -
FIG. 9A illustrates a top view of wearable device (e.g., watch) 900 that includes a firsttemperature sensing system 904 disposed at or near a front face of the wearable device 900 (e.g., approximately at the center of the front face) and one or more secondtemperature sensing systems wearable device 900. In some examples, the first temperature sensing system includes a dual heat flux sensor to measure a vertical gradient of the wearable device 900 (e.g., corresponding to temperature sensing system 500). In some examples, the second temperature sensing system includes a dual heat flux sensor to measure a lateral gradient at a lateral surface of the wearable device 900 (e.g., corresponding totemperature sensing system 500 but oriented laterally in the wearable device 900). In some examples, the second temperature sensing system includes a thermopile and an absolute temperature sensor to measure a lateral gradient at a lateral surface of thewearable device 900. In some examples, the second temperature sensing system includes two absolute temperature sensors to measure a lateral gradient at a lateral surface of thewearable device 900. As indicated by the dashed line labeled X-X′, structures of thewearable device 900 including one or more temperature sensing systems are further described with respect to the cross-section of thewearable device 900 as shown inFIG. 9B . - In some examples, a single temperature sensing system (e.g., first
temperature sensing system 904 inFIG. 9A ) is disposed at a face of thewearable device 900 and a single temperature sensing (e.g., a secondtemperature sensing system FIG. 9A ) is disposed at any side surface of the wearable device. As shown inFIG. 9A , the firsttemperature sensing system 904 is disposed at a central position on the front face of the wearable device 900 (e.g., at or near the center of a plane parallel to a watch face), and the secondtemperature sensing system FIG. 9A is a non-limiting example. In some examples, the firsttemperature sensing system 904 is disposed at any suitable position (e.g., off-center of the plane of the face), and the secondtemperature sensing system - In some examples, multiple temperature sensing systems measuring lateral gradients are disposed at multiple sides of the
wearable device 900. For example,temperature sensing system 906A is optionally disposed at or near a first side of thewearable device 900,temperature sensing system 906B is optionally disposed at or near a second side of thewearable device 900,temperature sensing system 906C is optionally disposed at or near a third side of thewearable device 900, andtemperature sensing system 906D is optionally disposed at or near a fourth side of thewearable device 900. Each of the fourtemperature sensing systems 906A-906D can measure a lateral temperature gradient for a respective side of the wearable device. In some examples, in addition to the first temperature sensing system measuring a vertical gradient, at least one additional temperature sensing system measuring a lateral gradient is disposed at a respective side of thewearable device 900. -
FIG. 9B illustrates a cross-sectional side view of wearable device (e.g., watch) 900 that includes a firsttemperature sensing system 904 disposed on a front face of thewearable device 900 and a second temperature sensing system 906 (e.g., corresponding totemperature sensing system 906A inFIG. 9A ) disposed at a representative side of thewearable device 900. As shown inFIG. 9B , the second temperature sensing system 956 measures a lateral gradient corresponding to a difference between T2 and T4. The secondtemperature sensing system 906 corresponds to the secondtemperature sensing system 906A ofFIG. 9A . In some examples, thewearable device 900 includes additional temperature sensing system(s) configured to measure additional lateral gradient(s). For example, the additional temperature sensing system(s) can correspond to the secondtemperature sensing system 906C ofFIG. 9A the details of which are not shown or repeated for brevity. -
FIG. 10 illustrates anexample process 1000 for measuring internal temperature and/or ambient temperature according to some examples of the disclosure. The measuring of internal temperature and/or ambient temperature can include computing operations based on measured temperatures from one or more absolute temperature sensors and from one or more thermopiles. Atblock 1002, processing circuitry of an electronic device (e.g.,electronic device 200, wearable device 150) can receive a thermal gradient associated with an inner thermopile and a thermal gradient associated with the outer thermopile. Temperature gradient measurements of thermopiles (e.g., inner thermopile, outer thermopile) can be used for determining heat flux. - At
block 1004, the processing circuitry can compute a thermal resistance of skin and internal body temperature based at least on the thermal gradient associated with the inner thermopile, the thermal gradient associated with the outer thermopile, a lateral temperature difference between the inner thermopile and the outer thermopile, and at least one absolute temperature (e.g., T1, T2, T3, or T4). Further, the processing circuitry can compute a thermal resistance of air and ambient temperature based at least on the thermal gradient associated with the inner thermopile, the thermal gradient associated with the outer thermopile, a lateral temperature difference between the inner thermopile and the outer thermopile, and at least one absolute temperature (e.g., T1, T2, T3, or T4). In some examples, the processing circuitry can compute the lateral temperature difference between the inner thermopile and the outer thermopile using an additional thermopile between the inner thermopile and the outer thermopile and/or at least one absolute temperature sensor. Atblock 1006, the processing circuitry can display the internal body temperature and/or ambient temperature via a display (e.g., corresponding to touch screen 152) of the wearable device. It is understood thatprocess 1000 illustrated inFIG. 10 is not limited to the operation as presented, but can include, fewer, additional, and/or simultaneous operations according to various examples. - Therefore, according to the above, some examples of the disclosure are directed to an electronic device. The electronic device can comprise a thermal sensing system. The thermal sensing system can comprise a sensing surface, where the sensing surface comprises an inner thermopile associated with a first heat path and an outer thermopile associated with a second heat path, where the inner thermopile is same in height as the outer thermopile, and where the inner thermopile and the outer thermopile form concentric geometries. The thermal sensing system can comprise a first absolute temperature configured to measure a first absolute temperature. The electronic device can comprise a processor communicatively coupled to the thermal sensing system and configured to compute an ambient temperature or body temperature using a first temperature gradient associated with the first heat path, a second temperature gradient associated with the second heat path, a lateral temperature difference between the inner thermopile and the outer thermopile, and the first absolute temperature. Additionally or alternatively to one or more of the examples disclosed above, in some examples, the processor can be configured to compute the ambient temperature or the body temperature using the first temperature gradient associated with the first heat path, the second temperature gradient associated with the second heat path, and at least two absolute temperatures. Additionally or alternatively to one or more of the examples disclosed above, in some examples, the first absolute temperate sensor can be configured to measure a first absolute temperature at a first surface of the inner thermopile. The thermal sensing system can comprise a second absolute temperate sensor configured to measure a second absolute temperature at a first surface of the outer thermopile. Additionally or alternatively to one or more of the examples disclosed above, in some examples, the processor can be configured to compute the ambient temperature or the body temperature using the first temperature gradient associated with the first heat path, a second temperature gradient associated with the second heat path, and at least two absolute temperatures. Additionally or alternatively to one or more of the examples disclosed above, in some examples, the processor can be configured to compute the lateral temperature difference between the inner thermopile and the outer thermopile using the first absolute temperature and the second absolute temperature. Additionally or alternatively to one or more of the examples disclosed above, in some examples, processor can be configured to compute the lateral temperature difference between the inner thermopile and the outer thermopile using a surface thermopile disposed between the inner thermopile and the outer thermopile. Additionally or alternatively to one or more of the examples disclosed above, in some examples, the processor can be configured to compute the ambient temperature using the first temperature gradient, the second temperature gradient, the lateral temperature difference between the inner thermopile and the outer thermopile, a first surface area of the first heat path exposed to the ambient temperature, a second surface area of the second heat path exposed to the ambient temperature, a first resistance associated with the first heath path, and a second resistance associated with the second heat path. Additionally or alternatively to one or more of the examples disclosed above, in some examples, the sensing surface can comprise glass or a printed circuit board. Additionally or alternatively to one or more of the examples disclosed above, in some examples, the inner thermopile can comprise a first set of metal fillings and the outer thermopile can comprise a second set of metal fillings different from the first set of metal fillings. Additionally or alternatively to one or more of the examples disclosed above, in some examples, the first set of metal fillings can comprise copper and constantan and the second set of metal fillings can comprise chromel and constantan. Additionally or alternatively to one or more of the examples disclosed above, in some examples, the thermal sensing system can comprise a passivation layer disposed on the sensing surface, and the passivation layer can comprise epoxy, silicon nitride, glass, a polymer material, a ceramic material, a composite material, or any combination thereof. Additionally or alternatively to one or more of the examples disclosed above, in some examples, the thermal sensing system can comprise a thermal insulation layer disposed a threshold distance from the outer thermopile. Additionally or alternatively to one or more of the examples disclosed above, in some examples, the concentric geometries can comprise concentric cylinders. Some examples of the disclosure are directed to a method of operating the system described herein or a non-transitory computer readable storage medium storing instructions configured to be executed by one or more processors of the system to cause the processor(s) to perform any of the above operations of the system.
- Some examples of the disclosure are directed to a dual heat flux sensor. The dual heat flux sensor can comprise a sensing glass comprising an inner thermopile and an outer thermopile, where the inner thermopile and the outer thermopile are uniform in height and form concentric geometries. The dual heat flux sensor can comprise a plurality of vias in the sensing glass comprising a plurality of first vias from a first surface of the sensing glass to a second surface of the sensing glass and a plurality of second vias from the first surface of the sensing glass to the second surface of the sensing glass, where the inner thermopile is formed from a first set of conductive materials filling the plurality of first vias and the outer thermopile is formed from a second set of conductive materials filling the plurality of second vias. The dual heat flux sensor can comprise sensing circuitry configured to measure a temperature gradient associated with the inner thermopile and a second temperature gradient associated with the outer thermopile. Additionally or alternatively to one or more of the examples disclosed above, in some examples, the first set of conductive materials can be different than the second set of conductive materials. Additionally or alternatively to one or more of the examples disclosed above, in some examples, a diameter of the dual heat flux sensor can be at least 1.5 times greater than a diameter of the outer thermopile. Additionally or alternatively to one or more of the examples disclosed above, in some examples, a diameter of the dual heat flux sensor can be between 9 millimeters and 12 millimeters. Additionally or alternatively to one or more of the examples disclosed above, in some examples, a height of the dual heat flux sensor can be less than 4 millimeters. Additionally or alternatively to one or more of the examples disclosed above, in some examples, the dual heat flux sensor can comprise a housing coupled to the sensing glass, the housing can comprise a cavity disposed beneath the sensing glass, and the cavity can comprise air. Additionally or alternatively to one or more of the examples disclosed above, in some examples, the cavity can comprise a height between 0.5 millimeters and 2.5 millimeters. Additionally or alternatively to one or more of the examples disclosed above, in some examples, the dual heat flux sensor can comprise a glass layer different from the sensing glass and disposed beneath the sensing glass. Some examples of the disclosure are directed to a method of operating the system described herein or a non-transitory computer readable storage medium storing instructions configured to be executed by one or more processors of the system to cause the processor(s) to perform any of the above operations of the system.
- Some examples of the disclosure are directed to a method. The method can include measuring one or more absolute temperatures; measuring a first thermal gradient associated with a first thermopile and a second thermal gradient associated with a second thermopile from a dual heat flux sensor; and computing an ambient temperature or an internal body temperature using the first thermal gradient, the second thermal gradient, a lateral temperature difference between the first thermopile and the second thermopile, the one or more absolute temperatures, or any combination thereof. Additionally or alternatively to one or more of the examples disclosed above, in some examples, the method can include computing the lateral temperature difference between the first thermopile and the second thermopile using a third thermopile disposed between the first thermopile and the second thermopile or the one or more absolute temperature sensors. Additionally or alternatively to one or more of the examples disclosed above, in some examples, the method can include outputting (e.g., displaying) an internal body temperature or ambient temperature. Some examples of the disclosure are directed to a non-transitory computer readable storage medium storing instructions configured to be executed by one or more processors of the system to cause the processor(s) to perform any of the above operations of the system.
- Some examples of the disclosure are directed to a non-transitory computer readable storage medium. The non-transitory computer readable storage medium storing instructions configured to be executed by one or more processors of the system to cause the processor(s) to: measure one or more absolute temperatures; measure a first thermal gradient associated with a first thermopile and a second thermal gradient associated with a second thermopile from a dual heat flux sensor; and compute an ambient temperature or an internal body temperature using the first thermal gradient, the second thermal gradient, a lateral temperature difference between the first thermopile and the second thermopile, the one or more absolute temperatures, or any combination thereof. Additionally or alternatively to one or more of the examples disclosed above, in some examples, the instructions, when executed by one or more processors of the system, cause the processor(s) to: compute the lateral temperature difference between the first thermopile and the second thermopile using a third thermopile disposed between the first thermopile and the second thermopile or the one or more absolute temperature sensors. Additionally or alternatively to one or more of the examples disclosed above, in some examples, the instructions, when executed by one or more processors of the system, cause the processor(s) to: output (e.g., displaying) an internal body temperature or ambient temperature. Some examples of the disclosure are directed to a method of operating the system described herein.
- Some examples of the disclosure are directed to a system. The system can comprise a first absolute temperature sensor configured to measure a first absolute temperature at a first surface of an inner thermopile, a second absolute temperature sensor configured to measure a second absolute temperature at a first surface of an outer thermopile, a third absolute temperature sensor configured to measure a third absolute temperature at a second surface of the inner thermopile, and a fourth absolute temperature sensor configured to measure a fourth absolute temperature at a second surface of the outer thermopile. Further, the system can comprise a processor communicatively coupled to the first absolute temperature sensor, the second absolute temperature sensor, the third absolute temperature sensor, and the fourth absolute temperature sensor and configured to compute an ambient temperature or an internal body temperature using the first absolute temperature, the second absolute temperature, the third absolute temperature, and the fourth absolute temperature. Some examples of the disclosure are directed to a method of operating the system described herein or a non-transitory computer readable storage medium storing instructions configured to be executed by one or more processors of the system to cause the processor(s) to perform any of the above operations of the system.
- Some examples of the disclosure are directed to a system. The system can comprise a first temperature sensing system configured to measure one or more vertical gradients and a second temperature sensing system configured to measure one or more lateral gradients. Additionally or alternatively to one or more of the examples disclosed above, in some examples, the first temperature sensing system includes a first dual heat flux sensor and/or a second dual heat flux sensor. The first dual heat flux sensor and/or the second dual heat flux sensor can correspond to any of the above described heat flux sensors. For example, a respective dual heat flux sensor can comprise a sensing glass, a plurality of vias in the sensing glass, and sensing circuitry. The sensing glass can comprise an inner thermopile and an outer thermopile, where the inner thermopile and the outer thermopile are uniform in height and form concentric geometries. The plurality of vias in the sensing glass can comprise a plurality of first vias from a first surface of the sensing glass to a second surface of the sensing glass and a plurality of second vias from the first surface of the sensing glass to the second surface of the sensing glass, where the inner thermopile is formed from a first set of conductive materials filling the plurality of first vias and the outer thermopile is formed from a second set of conductive materials filling the plurality of second vias. Sensing circuitry can be configured to measure a temperature gradient associated with the inner thermopile and a second temperature gradient associated with the outer thermopile.
- Some examples of the disclosure are directed to a wearable device. The wearable device can comprise a temperature sensing system configured to measure one or more vertical gradients and one or more temperature sensing systems configured to measure one or more lateral gradients. Additionally or alternatively to one or more of the examples disclosed above, in some examples, one or more temperature sensing systems configured to measure one or more lateral gradients can include a first temperature sensing system configured to measure a first lateral gradient corresponding to a first side of the wearable device, a second temperature sensing system configured to measure a second lateral gradient corresponding to a second side of the wearable device, a third temperature sensing system configured to measure a third lateral gradient corresponding to a third side of the wearable device, and a fourth temperature sensing system configured to measure a fourth lateral gradient corresponding to a fourth side of the wearable device. Additionally or alternatively to one or more of the examples disclosed above, in some examples, the temperature sensing system configured to measure the vertical gradient and/or the one or more temperature sensing systems configured to measure the one or more lateral gradients can comprise a dual heat flux sensor corresponding to any of the above described heat flux sensors. For example, a respective dual heat flux sensor can comprise a sensing glass, a plurality of vias in the sensing glass, and sensing circuitry. The sensing glass can comprise an inner thermopile and an outer thermopile, where the inner thermopile and the outer thermopile are uniform in height and form concentric geometries. The plurality of vias in the sensing glass can comprise a plurality of first vias from a first surface of the sensing glass to a second surface of the sensing glass and a plurality of second vias from the first surface of the sensing glass to the second surface of the sensing glass, where the inner thermopile is formed from a first set of conductive materials filling the plurality of first vias and the outer thermopile is formed from a second set of conductive materials filling the plurality of second vias. Sensing circuitry can be configured to measure a temperature gradient associated with the inner thermopile and a second temperature gradient associated with the outer thermopile.
- Although examples of this disclosure have been fully described with reference to the accompanying drawings, it is to be noted that various changes and modifications will become apparent to those skilled in the art. Such changes and modifications are to be understood as being included within the scope of examples of this disclosure as defined by the appended claims.
Claims (20)
1. An electronic device, comprising:
a thermal sensing system comprising:
a sensing surface, wherein the sensing surface comprises an inner thermopile associated with a first heat path and an outer thermopile associated with a second heat path, wherein the inner thermopile is same in height as the outer thermopile, and wherein the inner thermopile and the outer thermopile form concentric geometries; and
a first absolute temperature sensor configured to measure a first absolute temperature; and
a processor communicatively coupled to the thermal sensing system and configured to compute an ambient temperature or body temperature using a first temperature gradient associated with the first heat path, a second temperature gradient associated with the second heat path, a lateral temperature difference between the inner thermopile and the outer thermopile, and the first absolute temperature.
2. The electronic device of claim 1 , wherein the processor is configured to compute the ambient temperature or the body temperature using the first temperature gradient associated with the first heat path, the second temperature gradient associated with the second heat path, and at least two absolute temperatures.
3. The electronic device of claim 1 , wherein the first absolute temperature sensor is configured to measure the first absolute temperature at a first surface of the inner thermopile, wherein the thermal sensing system comprises a second absolute temperature sensor configured to measure a second absolute temperature at a first surface of the outer thermopile.
4. The electronic device of claim 3 , wherein the processor is configured to compute the lateral temperature difference between the inner thermopile and the outer thermopile using the first absolute temperature and the second absolute temperature.
5. The electronic device of claim 1 , wherein the processor is configured to compute the lateral temperature difference between the inner thermopile and the outer thermopile using a surface thermopile disposed between the inner thermopile and the outer thermopile.
6. The electronic device of claim 1 , wherein the processor is configured to compute the ambient temperature using the first temperature gradient, the second temperature gradient, the lateral temperature difference between the inner thermopile and the outer thermopile, a first surface area of the first heat path exposed to the ambient temperature, a second surface area of the second heat path exposed to the ambient temperature, a first resistance associated with the first heat path, and a second resistance associated with the second heat path.
7. The electronic device of claim 1 , wherein the sensing surface comprises glass or a printed circuit board.
8. The electronic device of claim 1 , wherein the inner thermopile comprises a first set of metal fillings and the outer thermopile comprises a second set of metal fillings different from the first set of metal fillings.
9. The electronic device of claim 8 , wherein the first set of metal fillings comprises copper and constantan and the second set of metal fillings comprises chromel and constantan.
10. The electronic device of claim 1 , wherein the thermal sensing system comprises a passivation layer disposed on the sensing surface, wherein the passivation layer comprises epoxy, silicon nitride, glass, a polymer material, a ceramic material, a composite material, or any combination thereof.
11. The electronic device of claim 1 , wherein the thermal sensing system comprises a thermal insulation layer disposed a threshold distance from the outer thermopile.
12. The electronic device of claim 1 , wherein the concentric geometries comprise concentric cylinders.
13. A dual heat flux sensor, comprising:
a sensing glass comprising an inner thermopile and an outer thermopile, wherein the inner thermopile and the outer thermopile are uniform in height and form concentric geometries;
a plurality of vias in the sensing glass comprising a plurality of first vias from a first surface of the sensing glass to a second surface of the sensing glass and a plurality of second vias from the first surface of the sensing glass to the second surface of the sensing glass, wherein the inner thermopile is formed from a first set of conductive materials filling the plurality of first vias and the outer thermopile is formed from a second set of conductive materials filling the plurality of second vias; and
sensing circuitry configured to measure a temperature gradient associated with the inner thermopile and a second temperature gradient associated with the outer thermopile.
14. The dual heat flux sensor of claim 13 , wherein a diameter of the dual heat flux sensor is at least 1.5 times greater than a diameter of the outer thermopile.
15. The dual heat flux sensor of claim 13 , wherein a diameter of the dual heat flux sensor is between 9 millimeters and 12 millimeters.
16. The dual heat flux sensor of claim 13 , wherein a height of the dual heat flux sensor is less than 4 millimeters.
17. The dual heat flux sensor of claim 13 , wherein the dual heat flux sensor comprises a housing coupled to the sensing glass, wherein the housing comprises a cavity disposed beneath the sensing glass, and wherein the cavity comprises air.
18. The dual heat flux sensor of claim 17 , wherein the cavity comprises a height between 0.5 millimeters and 2.5 millimeters.
19. The dual heat flux sensor of claim 13 , comprising a glass layer different from the sensing glass and disposed beneath the sensing glass.
20. A system, comprising:
a first absolute temperature sensor configured to measure a first absolute temperature at a first surface of an inner thermopile;
a second absolute temperature sensor configured to measure a second absolute temperature at a first surface of an outer thermopile;
a third absolute temperature sensor configured to measure a third absolute temperature at a second surface of the inner thermopile;
a fourth absolute temperature sensor configured to measure a fourth absolute temperature at a second surface of the outer thermopile; and
a processor communicatively coupled to the first absolute temperature sensor, the second absolute temperature sensor, the third absolute temperature sensor, and the fourth absolute temperature sensor and configured to compute an ambient temperature or an internal body temperature using the first absolute temperature, the second absolute temperature, the third absolute temperature, and the fourth absolute temperature.
Priority Applications (3)
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US18/353,040 US20240060832A1 (en) | 2022-08-18 | 2023-07-14 | Dual heat path temperature sensor |
EP23191664.4A EP4328557A1 (en) | 2022-08-18 | 2023-08-16 | Dual heat path temperature sensor |
CN202311036375.9A CN117589319A (en) | 2022-08-18 | 2023-08-17 | Dual thermal path temperature sensor |
Applications Claiming Priority (2)
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US202263371820P | 2022-08-18 | 2022-08-18 | |
US18/353,040 US20240060832A1 (en) | 2022-08-18 | 2023-07-14 | Dual heat path temperature sensor |
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US11635334B2 (en) * | 2020-06-30 | 2023-04-25 | Apple Inc. | Miniature external temperature sensing device for estimating subsurface tissue temperatures |
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